Synchronization control for reconnecting microgrid to main grid after islanding

What is claimed is: 1. A method, comprising: synchronously reconnecting a microgrid to a main grid after islanding of the microgrid, wherein said synchronously reconnecting step comprises: calculating a phase angle difference between synchrophasor measurements collected from a common coupling on the main grid and synchrophasor measurements collected from a common coupling on the microgrid; calculating, by a controller, a frequency reference deviation based on the phase angle difference; and adjusting a frequency of the diesel generator based on the frequency reference deviation; wherein the data alignment comprises: storing the synchrophasor measurements from the point of common coupling on the main grid in a first buffer; storing the synchrophasor measurements from the point of common coupling on the main grid in a second buffer; determining, from measurement receive times at the first and second buffers, a leading one of the synchrophasor measurements from the point of common coupling on the main grid and the synchrophasor measurements from the point of common coupling on the microgrid; and removing, from a corresponding one of the first buffer or the second buffer, a number of measurements from the leading one. 2. The method of claim 1 , further comprising performing data alignment to align the synchrophasor measurements collected from the point of common coupling on the main grid with the synchrophasor measurements collected from the point of common coupling on the microgrid in preparation for said calculating step. 3. The method of claim 1 , further comprising adjusting a mechanical power output of the diesel generator. 4. The method of claim 1 , further comprising receiving the synchrophasor measurements over a communication channel using User Datagram Protocol multicast. 5. The method of claim 1 , further comprising extrapolating synchrophasor measurement values when the synchrophasor measurements from the point of common coupling on the main grid and the synchrophasor measurements from the point of common coupling on the microgrid are at least one of collected using different collection rates and reported using different reporting rates. 6. The method of claim 1 , wherein said step of adjusting the frequency of the diesel generator based on the frequency reference deviation comprises synchronizing a voltage phase angle at the common coupling on the main grid with a voltage phase angle at the common coupling on the microgrid. 7. The method of claim 1 , wherein the microgrid comprises a plurality of distributed generators, and the method further comprises: configuring one of the plurality of distributed generators as a master distributed generator; and configuring remaining ones of the plurality of distributed generators as slave distributed generators that follow an output voltage and an output frequency of the master distributed generator. 8. The method of claim 1 , further comprising disabling the method responsive to a received mode selection for an island mode that islands the microgrid from the main grid. 9. The method of claim 1 , further comprising enabling the method responsive to a received mode selection for a grid-tied mode that ties the main grid to the microgrid. 10. A method, comprising: synchronously reconnecting a microgrid to a main grid after islanding of the microgrid, wherein said synchronously reconnecting step comprises: calculating a phase angle difference between synchrophasor measurements collected from a common coupling on the main grid and synchrophasor measurements collected from a common coupling on the microgrid; calculating, by a controller, a frequency reference deviation based on the phase angle difference; adjusting a frequency of the diesel generator based on the frequency reference deviation; and adjusting the phase angle difference to lie within a predetermined range before calculating the frequency reference deviation therefrom. 11. A non-transitory article of manufacture tangibly embodying a computer readable program which when executed causes a computer to perform the steps of claim 1 . 12. A system, comprising: a controller for synchronously reconnecting a microgrid to a main grid after islanding of the microgrid, wherein said controller comprises: a processor-based phase angle difference calculator for calculating a phase angle difference between synchrophasor measurements collected from a common coupling on the main grid and synchrophasor measurements collected from a common coupling on the microgrid; a frequency reference deviation controller for calculating a frequency reference deviation based on the phase angle difference; a frequency adjuster for adjusting a frequency of the diesel generator based on the frequency reference deviation; and a model selection unit for blocking synchronization control operations between the main grid and the microgrid responsive to a received mode selection for a grid-tied mode that ties the main grid to the microgrid and enabling the synchronization control operations responsive to a received mode selection for an island mode that islands the microgrid from the main grid. 13. The system of claim 12 , further comprising a data aligner for performing data alignment to align the synchrophasor measurements collected from the point of common coupling on the main grid with the synchrophasor measurements collected from the point of common coupling on the microgrid in preparation for said calculating step. 14. The system of claim 12 , further comprising: a first buffer for storing the synchrophasor measurements from the point of common coupling on the main grid; and a second buffer for storing the synchrophasor measurements from the point of common coupling on the main grid, wherein the data aligner determines a leading one of, the synchrophasor measurements from the point of common coupling on the main grid and the synchrophasor measurements from the point of common coupling on the microgrid, based on measurement receive times at the first and second buffers, and wherein the data aligner causes a removal, from a corresponding one of the first buffer or the second buffer, of a number of measurements from the leading one. 15. The system of claim 12 , further comprising an engine control unit for adjusting a mechanical power output of the diesel generator. 16. The system of claim 12 , further comprising a phase angle adjuster for adjusting the phase angle difference to lie within a predetermined range before calculating the frequency reference deviation therefrom. 17. The system of claim 16 , wherein the phase angle adjustor adjusts the phase angle difference to compensate for a periodic feature of an electromagnetic wave. 18. The system of claim 12 , wherein the frequency adjuster adjusts the frequency of the diesel generator by synchronizing a voltage phase angle at the common coupling on the main grid with a voltage phase angle at the common coupling on the microgrid.