Constant current regulator for airfield ground lighting

What is claimed: 1. A constant current regulator for airfield ground lighting, comprising: a power converter configured to receive a first signal from an alternating current (AC) mains, wherein the power converter includes: a number of bi-directional switches; a transformer configured to isolate the first AC signal from an airfield ground lighting circuit; and a rectifier configured to convert the first AC signal from the AC mains from AC to a direct current (DC) signal; an inverter configured to receive the DC signal from the power converter and convert the DC signal to a second AC signal; an output filter configured to receive the second AC signal from the inverter and send the second AC signal to the airfield ground lighting circuit; and a controller configured to switch the number of bi-directional switches of the power converter to allow an input voltage and current of the second AC signal from the AC mains to be in phase; wherein the constant current regulator is connected to a particular relay of a number of relays included in an output redundancy module, wherein each respective relay of the number of relays is connected to a respective one of a number of constant current regulators, and wherein the particular relay is configured to bring the second AC signal into phase with other AC signals from the number of constant current regulators. 2. The constant current regulator of claim 1 , wherein the first controller is configured to switch the number of bi-directional switches of the power converter by pulse width modulation. 3. The constant current regulator of claim 2 , wherein the controller utilizes a voltage feedback from the rectifier for the pulse width modulation. 4. The constant current regulator of claim 2 , wherein the controller utilizes an input current feedback from the AC mains for the pulse width modulation. 5. The constant current regulator of claim 1 , wherein the number of bi-directional switches of the power converter are connected in a bridge configuration. 6. The constant current regulator of claim 1 , wherein the number of bi-directional switches, the transformer, and the rectifier are connected in series. 7. The constant current regulator of claim 1 , wherein the inverter includes: four switches connected in a bridge configuration; two diodes connected in parallel; and a capacitor connected in series with the two diodes and in parallel with the four switches; wherein the four switches are configured to be switched by an additional controller to convert the DC signal from the power converter to the second AC signal. 8. The constant current regulator of claim 1 , wherein the inverter includes: two switches connected in series; four diodes connected in a bridge configuration; and two capacitors connected in parallel with the four diodes and in parallel with the two switches; wherein the two switches are configured to be switched by an additional controller to convert the DC signal from the power converter to the second AC signal. 9. A method for controlling a constant current regulator for airfield ground lighting, comprising: receiving, by a power converter, a first alternating current (AC) signal from an AC mains, wherein the power converter includes four bi-directional switches; switching, by a controller, the four bi-directional switches by a predetermined switching cycle to allow an input voltage and current of the first AC signal from the AC mains to be in phase; isolating, by a transformer of the power converter, the first AC signal from an airfield ground lighting circuit; converting, by a rectifier of the power converter, the first AC signal from the transformer to a DC signal; converting, by an inverter, the DC signal from the rectifier to a second AC signal; outputting, by an output filter, the second AC signal from the inverter to the airfield ground lighting circuit; and bringing, by a particular relay connected to the constant current regulator, the second AC signal into phase with other AC signals from a number of constant current regulators, wherein: the particular relay connected to the constant current regulator is one of a number of relays included in an output redundancy module; and each respective relay of the number of relays is connected to a corresponding one of the number of constant current regulators. 10. The method of claim 9 , wherein the predetermined switching cycle includes: switching a first and a fourth of the bi-directional switches on and switching a second and a third of the bi-directional switches off for a first half of a positive portion of a period of the first AC signal from the AC mains; and switching the first and the fourth of the bi-directional switches off and switching the second and the third of the bi-directional switches on for a second half of the positive portion of the period of the first AC signal from the AC mains. 11. The method of claim 9 , wherein the predetermined switching cycle includes: switching a first and a fourth of the bi-directional switches on and switching a second and a third of the bi-directional switches off for a first half of a negative portion of a period of the first AC signal from the AC mains; and switching the first and the fourth of the bi-directional switches off and switching the second and the third of the bi-directional switches on for a second half of the negative portion of the period of the first AC signal from the AC mains. 12. The method of claim 9 , wherein converting the DC signal from the rectifier to the second AC signal includes switching, by an additional controller using sine pulse width modulation, a number of switches of the inverter. 13. A system for controlling constant current regulators for airfield ground lighting, comprising: a number of constant current regulator modules, wherein each of the number of constant current regulator modules include: a power converter configured to receive a first signal from an alternating current (AC) mains, wherein the power converter includes: a number of bi-directional switches configured to allow an input voltage and current of the first AC signal from the AC mains to be in phase; a transformer configured to isolate the first AC signal from an airfield ground lighting circuit; and a rectifier configured to convert the first AC signal from the AC mains to a direct current (DC) signal; an inverter configured to receive the DC signal from the power converter and convert the DC signal to a second AC signal; and an output filter configured to receive the second AC signal from the inverter; and an output redundancy module having a number of relays, wherein each respective relay of the number of relays is connected to a different one of the number of constant current regulator modules, and wherein each respective relay is configured to bring the second AC signal of the constant current regulator module to which it is connected into phase with other second AC signals of the other constant current regulator modules. 14. The system of claim 13 , wherein each respective constant current regulator module is configured to send a respective second AC signal to the respective relay to which it is connected and receive the respective second AC signal back from the relay until the respective second AC signal is in phase with the other second AC signals of the other constant current regulator modules. 15. The system of claim 13 , wherein each relay is configured to be normally closed. 16. The system of claim 13 , wherein each respective relay is configured to be switched open in response to the seco