Systems and methods for operating a power generating asset

What is claimed is: 1. A method for operating a power generating asset, the power generating asset comprising an energy storage device operably coupled to a component of the power generating asset, the method comprising: determining, with a controller, an open circuit voltage and an initial current of the energy storage device; initiating, with the controller, a state change event for the energy storage device, the state change event defining a plurality of sampling intervals; determining, with the controller, a change in a first electrical condition of the energy storage device by determining a difference between the open circuit voltage of the energy storage device before initiation of the state change event and an instantaneous voltage of the energy storage device at the plurality of sampling intervals of the state change event, the open circuit voltage being a top-of-charge voltage; determining, via the controller, a change in a second electrical condition of the energy storage device by determining a difference between the initial current of the energy storage device before initiation of the state change event and an instantaneous current of the energy storage device at each of the plurality of sampling intervals of the state change event; determining, via the controller, an actual equivalent series resistance (ESR) function for the energy storage device based on the changes in the first and second electrical conditions at each of the plurality of sampling intervals of the state change event; determining, via the controller, a state of health rating for the energy storage device based on the actual ESR function of the energy storage device; and implementing a control action based on the state of health rating. 2. The method of claim 1 , wherein determining the state of health rating for the energy storage device further comprises: modeling, via the controller, a nominal ESR function for the energy storage device at an ambient temperature, wherein the nominal ESR function corresponds to a maximal state of health rating at the ambient temperature; modeling, via the controller, at least one potential ESR function for the energy storage device at the ambient temperature, the at least one potential ESR function indicating an increased ESR value relative to a nominal ESR value as a function of the second electrical condition, the at least one potential ESR function corresponding to a reduced state of health rating at the ambient temperature; and consolidating, via the controller, the nominal ESR function and the at least one potential ESR function into at least one of a look up table, a graphical representation, and an algorithm so as to establish a correlation between the actual ESR function and the state of health rating for the energy storage device at the ambient temperature as a function of the second electrical condition of the energy storage device. 3. The method of claim 2 , further comprising: defining, via the controller, a plurality of temperature intervals across a nominal operating range of temperatures for the energy storage device, wherein a temperature interval of the plurality of temperature intervals corresponds to the ambient temperature; determining, via the controller, the nominal ESR function and the at least one potential ESR function at each temperature interval of the plurality of temperature intervals; and establishing a correlation between the actual ESR function and the state of health rating for the energy storage device at each temperature interval as a function of the second electrical condition of the energy storage device. 4. The method of claim 3 , wherein determining the state of health rating for the energy storage device further comprises determining the state of health rating corresponding to the determined actual ESR function at the ambient temperature of the energy storage device based on the correlation between the actual ESR function and the state of health rating. 5. The method of claim 1 , wherein implementing the control action further comprises: detecting an approach of the state of health rating to a state of health threshold; and generating an alert to facilitate scheduling of a maintenance event. 6. The method of claim 1 , wherein the state change event comprises at least one of a scheduled test event and a manipulation of the energy storage device during an operation of the power generating asset. 7. The method of claim 6 , wherein the scheduled test event is accomplished in conjunction with at least one additional component test of the power generating asset and results in an updating of the state of health rating. 8. The method of claim 1 , wherein the state change event comprises a discharging event of the energy storage device or a charging event of the energy storage device. 9. The method of claim 1 , wherein determining the actual ESR function further comprises determining the actual ESR function as a function of the second electrical condition and independent of a first electrical condition discharge profile and a second electrical condition discharge profile. 10. The method of claim 1 , further comprising: receiving, via the controller, at least one of a cycle count and a time count elapsed from an installation date; determining, via the controller, a correlation between the state of health rating and the received at least one of the cycle count and the time count, wherein the correlation is indicative of a rate of degradation of the energy to storage device per at least one of the cycle count and the time count; determining a state of health threshold for the energy storage device; and based on the correlation and the state of health threshold, determining, via the controller, at least one of a number of cycles and time until the state of health threshold is reached. 11. A system for operating a power generating asset, the system comprising: an energy storage device operably coupled to a component of the power generating asset; and a controller communicatively coupled to the energy storage device, the controller comprising at least one processor configured to perform a plurality of operations, the plurality of operations comprising: determining an open circuit voltage and an initial current of the energy storage device; initiating a state change event for an energy storage device, the state change event defining a plurality of sampling intervals; determining a change in a first electrical condition of the energy storage device by determining a difference between the open circuit voltage of the energy storage device before initiation of the state change event and an instantaneous voltage of the energy storage device at the plurality of sampling intervals of the state change event, the open circuit voltage being a top-of-charge voltage; determining a change in a second electrical condition of the energy storage device by determining a difference between the initial current of the energy storage device before initiation of the state change event and an instantaneous current of the energy storage device at each of the plurality of sampling intervals of the state change event; determining an actual equivalent series resistance (ESR) function for the energy storage device based on the changes in the first and the second electrical conditions at each of the plurality of sampling intervals of the state change event; determining a state of health rating for the energy storage device based on the actual ESR function of the energy storage device; and implementing a control action based on the state of health rating. 12. The system of claim 11 , wherein determining the state of health rating for the en