Robust control for optimized islanded and grid-connected operation of solar/wind/battery hybrid energy systems

The invention claimed is: 1. A method to control a hybrid renewable microgrid system, wherein the hybrid renewable microgrid system comprises a solar energy generation unit and an energy storage unit in direct connection to a DC bus, a DC-DC buck-boost converter connected to the energy storage unit, a wind energy generation unit coupled to a rotor-side converter, a grid-side converter coupled to the DC bus, and a microgrid load; and wherein a utility grid comprising a plurality of energy generation sources and one or more utility grid loads is electrically coupled to the hybrid renewable microgrid system; the method comprising: performing a maximum power point tracking control for each of the solar energy generation unit and the wind energy generation unit; receiving a power from the wind energy generation unit utilizing the rotor-side converter and receiving a power from the solar energy generation unit utilizing the grid-side converter; supplying at least one of (1) a first power to the microgrid load of the hybrid renewable microgrid system in a standalone operation of the hybrid renewable microgrid system and (2) a second power to a combination of the microgrid load of the hybrid renewable microgrid system and the one or more utility grid loads of the utility grid in a grid-connected operation of the hybrid renewable microgrid system; receiving a third power from the plurality of energy generation sources of the utility grid utilizing the rotor-side converter in the grid-connected operation of the hybrid renewable microgrid system; performing a sliding mode control for at least one of a transition from the standalone operation to the grid-connected operation and a transition from the grid-connected operation to the standalone operation; controlling the supply of the second power in the grid-connected operation by integrating the wind energy generation unit into the utility grid through the rotor-side converter and the grid-side converter; regulating a microgrid load voltage of the microgrid load in the grid-connected operation of receiving the third power using a charging and/or discharging of the energy storage unit; controlling the charging and/or discharging of the energy storage unit using the DC-DC buck-boost converter in the standalone operation and the grid-connected operation of the hybrid renewable microgrid system; and regulating the microgrid load voltage through performing the maximum power point tracking control, the sliding mode control, and the charging and discharging of the energy storage unit in the standalone operation and the grid-connected operation of the hybrid renewable microgrid system. 2. The method of claim 1 , comprising charging the energy storage unit using the DC-DC buck-boost converter, wherein at least one of: a sum value of power received from the solar energy generation unit and the power received from the wind energy generation unit greater than at least one of the first power and the second power; and a sum value of power received from the solar energy generation unit, the power received from the wind energy generation unit, and the power received from the plurality of energy generation sources of the utility grid greater than at least one of the first power and the second power. 3. The method of claim 1 , comprising discharging the energy storage unit using the DC-DC buck-boost converter, wherein at least one of a sum value of power received from the solar energy generation unit and the power received from the wind energy generation unit lower than at least one of the first power and the second power; and a sum value of power received from the solar energy generation unit, the power received from the wind energy generation unit, and the power received from the plurality of energy generation sources of the utility grid lower than at least one of the first power and the second power. 4. The method of claim 1 , further comprising converting an AC signal output of the wind energy generation unit to a DC signal using the rotor-side converter. 5. The method of claim 1 , further comprising converting a plurality of DC signal outputs from the DC bus to a plurality of three-phase AC signals for supplying at least one of the first power and the second power using the grid-side converter. 6. The method of claim 1 , further comprising converting a plurality of AC signals of the third power to a plurality of DC signals using the grid-side converter. 7. The method of claim 1 , further comprising utilizing a diode connected in series and downstream to the solar energy generation unit for absorbing a reverse current from the DC bus. 8. The method of claim 1 , further comprising stabilizing a DC voltage of the DC-bus through performing the maximum power point tracking control, the sliding mode control, and the charging and discharging of the energy storage unit. 9. The method of claim 1 , further comprising triggering the sliding mode control through at least one of an ON state and an OFF state of a switch connected between the microgrid load of the hybrid renewable microgrid system and the utility grid. 10. The method of claim 1 , further comprising connecting the rotor-side converter and the grid-side converter in a back-to-back converter configuration. 11. A power system, comprising: a hybrid renewable microgrid system, comprising a multiple-input multiple-output controller, comprising a rotor-side converter and a grid-side converter arranged in a back-to-back converter configuration; and a DC-DC buck-boost converter; a solar energy generation unit including one or more photovoltaic panels connected in series and parallel; a wind energy generation unit including a wind turbine coupled to a permanent magnet synchronous generator, wherein the permanent magnet synchronous generator is coupled to the rotor-side converter; a DC bus, wherein the solar energy generation unit is in direct connection to the DC bus, and wherein the DC bus is connected to the grid-side converter; an energy storage unit integrated to the DC-DC buck-boost converter and connected to the DC bus; and a microgrid load coupled to the grid-side converter; and a utility grid, comprising: a plurality of energy generation sources; and one or more utility grid loads; wherein the multiple-input multiple-output controller is configured to perform a maximum power point tracking control to receive power from the solar energy generation unit and the wind energy generation unit; wherein the multiple-input multiple-output controller is configured to perform a sliding mode control for a transition between a standalone operation and a grid-connected operation of the hybrid renewable microgrid system; wherein the hybrid renewable microgrid system is electrically disconnected from the utility grid in the standalone operation; wherein the hybrid renewable microgrid system is configured to perform at least one of supplying a power to the one or more utility loads of the utility grid and receiving a power from the plurality of energy generation sources of the utility grid in the grid-connected operation; and wherein the multiple-input multiple-output controller is configured to regulate a microgrid load voltage of the microgrid load and a DC voltage of the DC bus. 12. The hybrid renewable microgrid system of claim 11 , wherein the DC-DC buck-boost converter is configured to transfer power from the energy storage unit of the hybrid renewable microgrid system, to at least one of the wind energy generation unit, the solar energy generation unit and the utility grid through the discharging of the energy storage unit. 13. The hy