Fault recovery controller for integrated solar PV system

The invention claimed is: 1. A reactive power support system for a radial distribution network, comprising: a radial distribution transmission line connected at a first end to a grid transformer; a plurality of loads, wherein each load is connected by a load bus to the radial distribution transmission line; a point of common coupling connected to a second end of the radial distribution transmission line; a photovoltaic module; a solar power inverter connected in parallel with the photovoltaic module, wherein the solar power inverter has an output terminal configured to connect to the point of common coupling; and an inverter controller connected to the solar power inverter, wherein the inverter controller is configured to provide gate control signals which switch a set of transistor gates of the solar power inverter to operate at less than or greater than a unity power factor to provide reactive power or to absorb reactive power respectively at the point of common coupling in order to regulate a voltage of the radial distribution transmission line during a three-phase to ground fault on a load bus connected to one of the loads. 2. The reactive power support system of claim 1 , wherein the gate control signals are configured to switch the set of transistor gates of the solar power inverter to provide active power to the point of common coupling when the radial distribution transmission line is balanced. 3. The reactive power support system of claim 1 , further comprising: a capacitor in parallel with the photovoltaic module and the solar power inverter; and an inductor connected between the photovoltaic module and the solar power inverter. 4. The reactive power support system of claim 3 , wherein the set of transistor gates comprise: a first transistor S 11 having its collector connected to a positive terminal of the capacitor and its emitter connected to the point of common coupling by a first phase transmission line; a second transistor S 12 having its collector connected to the first phase transmission line and its emitter connected to a ground terminal; a third transistor S 21 having its collector connected to a positive terminal of the capacitor and its emitter connected to the point of common coupling by a second phase transmission line; a fourth transistor S 22 having its collector connected to the second phase transmission line and its emitter connected to the ground terminal; a fifth transistor S 31 having its collector connected to a positive terminal of the capacitor and its emitter connected to the point of common coupling by a third phase transmission line; a sixth transistor S 32 having its collector connected to the third phase transmission line and its emitter connected to the ground terminal; and a reversed biased diode in parallel with each transistor of the set of transistors, wherein a gate of each transistor of the set of transistor gates is configured to connect to a respective one of the gate control signals. 5. The reactive power support system of claim 1 , wherein the inverter controller is configured to provide gate control signals that operate the solar power inverter at: greater than a unity power factor when the reactive power at the point of common coupling is less than a grid reference value, unity power factor when the reactive power at the point of common coupling equals the grid reference value, and less than the unity power factor when the reactive power at the point of common coupling is greater than the grid reference value. 6. The reactive power support system of claim 5 , wherein the inverter controller comprises: an adder configured to receive a voltage reference signal at a positive input terminal, a point of common coupling voltage at a negative input terminal, add the voltage reference signal to the negative point of common coupling voltage and generate an error signal at an output terminal; a proportional integral controller connected in series with the adder, wherein the proportional integral controller is configured to sample the error signal during a time window, average the error signals and generate an average error signal; and a pulse width modulator connected in series with the proportional integral controller, wherein the pulse width modulator is configured to receive the average error signal and generate gate control signals, wherein each gate control signal is configured to switch a polarity of the gate of a respective transistor of the solar power inverter to switch the respective transistor ON or OFF. 7. The reactive power support system of claim 5 , further comprising: a voltmeter connected between the point of common coupling and the output terminal of the solar power inverter, wherein the voltmeter is configured to measure the voltage at the point of common coupling; and a feedback transmission line connected between the voltmeter and the negative input of the adder, wherein the feedback transmission line is configured to transmit the voltage at the point of common coupling to the negative input of the adder. 8. The reactive power support system of claim 5 , further comprising: a grid network connected to the grid transformer, wherein the grid network includes a grid controller, wherein the grid controller is configured to transmit the voltage reference signal to the positive input terminal of the adder. 9. The reactive power support system of claim 8 , further comprising: an electrical distribution station connected to the grid network; and an on-load tap changer (OLTC) connected between the grid network and the grid transformer. 10. A method of providing reactive power support to a radial distribution network, comprising: connecting a first end of a radial distribution transmission line to a grid transformer; connecting a plurality of loads in parallel to the radial distribution transmission line; installing a photovoltaic module; connecting a solar power inverter in parallel with the photovoltaic module; connecting an output terminal of the solar power inverter to a point of common coupling at a second end of the radial distribution transmission line; connecting an inverter controller to the solar power inverter; measuring, with a voltmeter, a voltage at the point of common coupling; receiving, by the inverter controller, the voltage measured at the point of common coupling and a voltage reference value; and generating, by the inverter controller, gate control signals configured to switch a set of transistor gates of the solar power inverter to operate at less than or greater than a unity power factor to provide reactive power to or to absorb reactive power at the point of common coupling respectively when the voltage measured at the point of common coupling is less than or greater than the voltage reference value due to a three-phase to ground fault on a load bus connected to one of the loads. 11. The method of claim 10 , further comprising: generating, by the inverter controller, the gate control signals; transmitting the gate control signals to the set of transistor gates of the solar power inverter to provide active power to the point of common coupling when the voltage measured at the point of common coupling is equal to the voltage reference value. 12. The method of claim 10 , further comprising: connecting a capacitor in parallel with the photovoltaic module and the solar power inverter; and connecting an inductor in series with the photovoltaic module and the solar power inverter. 13. The method of claim 12 , further comprising: connecting the gate control signals to the solar power inverter, wherein the solar power inverter