System and method for providing grid-forming control of an inverter-based resource

What is claimed is: 1. A method for providing grid-forming (GFM) control of an inverter-based resource (IBR) connected to an electrical grid, the method comprising: monitoring the electrical grid for grid events that cause a change in one or both of grid frequency and angle; controlling, via a controller, an active power response of the IBR to the grid event by changing an angle of the IBR voltage relative to grid voltage in a manner so as to mimic an active power response of an IBR having a certain desired impedance; wherein the desired impedance is different than a hardware impedance of the IBR; estimating grid frequency and angle using a phase-locked loop (PLL), wherein changes in grid frequency and angle are reflected in a PLL frequency and a PLL error, wherein the PLL error becomes non-zero for rapid changes in grid frequency or angle, and further comprising calculating a first frequency component that is a derivative of the PLL error and a second frequency component that is proportional to the PLL error; and summing the first and second frequency components with the PLL frequency to obtain a high-bandwidth estimation of grid frequency; combining the high-bandwidth estimation of grid frequency with an inertial power regulator frequency; and integrating the combined high-bandwidth estimation of grid frequency and inertial power regulator frequency to generate an internal angle reference for grid-forming mode control of the IBR. 2. The method according to claim 1 , further comprising tuning gains applied to the first and second frequency components to be more or less aggressive to the grid events. 3. The method according to claim 2 , wherein limits are applied to high bandwidth components of estimated grid frequencies, the limits being fixed values or dynamically adjustable values. 4. The method according to claim 1 , further comprising applying a bandpass filter in parallel with the first and second frequency components, the bandpass filter tuned to a frequency to increase the effective impedance of the IBR at predetermined frequencies. 5. The method according to claim 1 , wherein the IBR is a double-fed wind turbine generator in a wind turbine power system connected to the electrical grid, the double-fed wind turbine generator coupled to a power converter having a line-side converter and a rotor-side converter coupled together via a DC link. 6. A system for controlling a power generating system in grid-forming (GFM) mode, the power system having an inverter-based resource (IBR) connected to an electrical grid, the system comprising: a controller comprising at least one processor, the at least one processor configured to perform a plurality of operations, the plurality of operations comprising: monitoring the electrical grid for grid events that cause a change in one or both of grid frequency and angle; and controlling an active power response of the IBR to the grid event by changing an angle of the IBR voltage relative to grid voltage in a manner that mimics an active power response of a GFM source having a certain desired impedance; wherein the controller is further configured to estimate grid frequency and angle using a phase-locked loop (PLL), wherein changes in grid frequency and angle are reflected in a PLL frequency and a PLL error, wherein the PLL error becomes non-zero for rapid changes in grid frequency or angle, the controller further configured to calculate a first frequency component that is a derivative of the PLL error and a second frequency component that is proportional to the PLL error; wherein the controller is further configured for: summing the first and second frequency components with the PLL frequency to obtain a high-bandwidth estimation of grid frequency; combining the high-bandwidth estimation of grid frequency with an inertial power regulator frequency; and integrating the combined high-bandwidth estimation of grid frequency and inertial power regulator frequency to generate an internal angle reference for grid-forming control of the IBR. 7. The system according to claim 6 , wherein the power generating system comprises a wind turbine power system and the IBR comprises a double-fed wind turbine generator connected to the electrical grid. 8. The system method according to claim 6 , wherein the controller is further configured to tune gains applied to the first and second frequency components to be more or less aggressive to the grid events. 9. A converter controller for providing grid-forming (GFM) control of an inverter-based resource (IBR) connected to an electrical grid, the converter controller comprising: a controller comprising at least one processor, the at least one processor configured to perform a plurality of operations, the plurality of operations comprising: monitoring the electrical grid for grid events that cause a change in one or both of grid frequency and angle; and controlling an active power response of the IBR to the grid event by changing an angle of the IBR voltage relative to grid voltage in a manner that mimics an active power response of a GFM source having a certain desired impedance; wherein the converter controller is further configured to estimate grid frequency and angle using a phase-locked loop (PLL), wherein changes in grid frequency and angle are reflected in a PLL frequency and a PLL error; and wherein the PLL error becomes non-zero for rapid changes in grid frequency or angle, the converter controller further configured to perform the following operations: calculate a first frequency component that is a derivate of the PLL error and a second frequency component that is proportional to the PLL error; sum the first and second frequency components with the PLL frequency to obtain a high-bandwidth estimation of grid frequency; combine the high-bandwidth estimation of grid frequency with an inertial power regulator frequency; and integrate the combined high-bandwidth estimation of grid frequency and inertial power regulator frequency to generate an internal angle reference for gating control of the IBR. 10. The converter controller according to claim 9 , wherein the IBR is a double-fed generator in a wind turbine power system connected to the electrical grid. 11. The converter controller according to claim 9 , wherein the converter controller is further configured to tune gains applied to the first and second frequency components to be more or less aggressive to the grid events. 12. The converter controller according to claim 11 , wherein the converter controller is further configured to apply a bandpass filter in parallel with the first and second frequency components, the bandpass filter tuned to a frequency to increase the effective impedance of the IBR at predetermined frequencies.