System and method for stability monitoring, analysis and control of electric power systems

What is claimed is: 1. A system for stability monitoring, analysis, and control in an energy system, the system comprising: a computer data repository configured to store physical data measured by at least one physical sensor; and a computing system comprising one or more computing devices, the computing system in communication with the computer data repository and programmed to implement: a stability analyzer configured to: retrieve the physical data from the computer data repository, wherein the physical data corresponds to a first power entity, and wherein the physical data comprises data of a first type; determine a plurality of growth rate values and a plurality of frequency values associated with the first power entity using the retrieved physical data and a spectral analysis technique, wherein each growth rate value in the plurality of growth rate values is associated with a frequency in a range of frequencies, and wherein each frequency value in the plurality of frequency values is associated with a frequency in the range of frequencies; determine a level of stability of the first power entity based on at least one growth rate value in the plurality of growth rate values; generate user interface data for rendering a user interface on a computing device, wherein the user interface data comprises a representation of the first power entity and an indication of the determined level of stability of the first power entity; and control the first power entity based on the determined level of stability of the first power entity. 2. The system of claim 1 , wherein the stability analyzer is further configured to assign a stability rank to the first power entity based on the determined level of stability of the first power entity, wherein the indication of the determined level of stability comprises an indication of the assigned stability rank. 3. The system of claim 2 , wherein a first color corresponds with the assigned stability rank, and wherein the representation of the first power entity is depicted in the first color. 4. The system of claim 1 , wherein the spectral analysis technique comprises a Koopman mode analysis. 5. The system of claim 1 , wherein the stability analyzer is further configured to receive, from a user, a request to adjust an actuator controlling the first power entity. 6. The system of claim 1 , wherein the user interface data further comprises a list of selectable frequencies, and a list of selectable data types, and wherein the stability analyzer is further configured to: determine a plurality of amplitudes and a plurality of phases associated with the first power entity using a Koopman mode analysis applied to the retrieved physical data, wherein each amplitude in the plurality of amplitudes is associated with a frequency in the range of frequencies, and wherein each phase in the plurality of phases is associated with a frequency in the range of frequencies; and update, in response to a selection of a first frequency within the list of selectable frequencies and a selection of the first type within the list of selectable data types, the user interface data to include, in association with the representation of the first power entity, a representation of the amplitude in the plurality of amplitudes that is associated with the first frequency. 7. The system of claim 6 , wherein the stability analyzer is further configured to: retrieve a stability limit associated with the first power entity; determine a time when the first power entity will reach the stability limit based on the plurality of growth rate values, the plurality of frequency values, and the plurality of amplitudes; generate an alert indicating the determined time; and update the user interface data to include the alert. 8. The system of claim 6 , wherein the stability analyzer is further configured to: generate a control sequence based on the determined plurality of phases; and transmit the control sequence to a control system such that the control system can adjust operation of the first power entity. 9. The system of claim 8 , wherein the control sequence includes an instruction that causes the first power entity to adjust operation in a way that opposes instability identified in the energy system. 10. The system of claim 1 , wherein the user interface data comprises one of a geographical map, a grip map, or a system schematic, and wherein the representation of the first power entity is positioned in the user interface over the one of the geographical map, the grip map, or the system schematic at a location that corresponds with a physical location of the first power entity. 11. The system of claim 1 , wherein the physical data comprises at least one of a value of voltages generated by the first power entity, a phase of the voltages generated by the first power entity, a value of current generated by the first power entity, a power level output by the first power entity, reactive power, apparent power, power quality, rotor angular position of a power source, rotor angular velocity of a power source, rotor frequency of a power source, mechanical input power of a power source, an amount of power demanded by the first power entity, an amount of power consumed by the first power entity, or social data. 12. The system of claim 1 , wherein the stability analyzer is further configured to generate a control sequence that causes a storage system to release energy into the energy system based on the determined level of stability of the first power entity. 13. The system of claim 1 , wherein the first power entity is one of a power source or a power sink. 14. A method for stability monitoring, analysis, and control in an energy system, the method comprising: as implemented by a computer system comprising one or more computing devices, the computer system configured with specific executable instructions, retrieving physical data, wherein the physical data is measured by at least one physical sensor and corresponds to a first power entity, and wherein the physical data comprises data of a first type; determining a plurality of growth rate values associated with the first power entity using the retrieved physical data and a spectral analysis technique, wherein one or more individual growth rate values in the plurality of growth rate values are associated with a frequency in a range of frequencies; determining a level of stability of the first power entity based on at least one growth rate value in the plurality of growth rate values; generating user interface data for rendering a user interface on a computing device, wherein the user interface data comprises a representation of the first power entity and an indication of the determined level of stability of the first power entity; and controlling the first power entity based on the determined level of stability of the first power entity. 15. The method of claim 14 , further comprising assigning a stability rank to the first power entity based on the determined level of stability of the first power entity, wherein the indication of the determined level of stability comprises an indication of the assigned stability rank. 16. The method of claim 15 , wherein a first color corresponds with the assigned stability rank, and wherein the representation of the first power entity is depicted in the first color. 17. The method of claim 14 , wherein the spectral analysis technique comprises a Koopman mode analysis. 18. The method of claim 14 , further comprising receiving, from a user, a request to adjust an actuator control