Method for controlling a wind farm

The invention claimed is: 1. A method for controlling a wind power system for feeding electrical power generated from wind into an electrical supply grid and for damping low-frequency oscillations in the electrical supply grid, wherein the electrical supply grid has a line voltage with a nominal line frequency, wherein low-frequency oscillations are frequency oscillations that are less than one half of the nominal line frequency, the method comprising: performing, by a closed control circuit, damping control for damping the low-frequency oscillations, and controlling, by the damping control, a feed-in of the electrical power into the electrical supply grid using a wind system controller, wherein the closed control circuit includes: at least a portion of the electrical supply grid, at least a portion of the wind power system, and at least a portion of the wind system controller, and wherein the damping control is configured to mitigate weakly-damped modes in the closed control circuit, wherein the damping control includes modeling a network characteristic including oscillation properties, wherein modeling the network characteristic includes: modeling a network that represents at least a portion of the electrical supply grid included in the closed control circuit and accounts for a structure of the at least the portion of the electrical supply grid and consumers and producers connected to the at least the portion of the electrical supply grid; and modeling a wind system which represents a behavior of the wind power system, wherein modeling the wind system also includes a behavior of the wind system controller, and wherein the method further comprises: linearizing the modeled network characteristic to obtain a linearized network characteristic, wherein the linearizing is with respect to at least one working point, and configuring the damping control based on the linearized network characteristic. 2. The method as claimed in claim 1 , comprising: modeling, by varying operational points of the wind power system, a plurality of linearized working points, each reflecting an oscillation behavior, for configuring the damping control; and configuring the damping control, based on the plurality of modeled linearized working points, such that, for each of the plurality of modeled linearized working points, the damping control mitigates weakly-damped modes in the closed control circuit. 3. The method as claimed in claim 1 , comprising: receiving, by the wind system controller, at least one electrical voltage of the electrical supply grid as an input; and outputting, by the wind system controller, at least one electrical output current for feeding into the electrical supply grid. 4. The method as claimed in claim 1 , comprising: configuring the damping control as multi-variable control; receiving at least one electrical voltage of the electrical supply grid as a first input; and receiving, as a second input, at least one variable from a list including: an electrical intermediate circuit voltage of a direct voltage intermediate circuit of an electrical inverter; a reactive power output by the electrical inverter; an electrical generator power of a generator of a wind power installation; and a speed of the generator; and at least one blade angle of adjustable rotor blades of the wind power installation. 5. The method as claimed in claim 1 , further comprising modeling at least one simplified working point, wherein the damping control includes a damping parameter determined from an eigenvalue analysis and/or a modal analysis of the at least one modeled simplified working point, wherein the at least one modeled simplified working point is linearized to obtain the at least one modeled linearized working point. 6. The method as claimed in claim 1 , wherein modeling the network characteristic includes modeling a generator characteristic that emulates a behavior of synchronous generators directly coupled to the electrical supply grid. 7. The method as claimed in claim 1 , comprising: determining and storing a plurality of damping parameter sets; determining between a plurality of control structures (state controller—first order and second order PID controller or PI controller) for the damping control; selecting, based on a selection criterion, one of the plurality of damping parameter sets and/or the plurality of control structures for operating the wind power system; and switching between the plurality of damping parameter sets and/or the plurality of control structures during operation of the wind power system. 8. The method as claimed in claim 7 , wherein the selection criterion is one of: an external signal of a grid operator; a time of day; a day of week; a calendar day; a state of the electrical supply grid; and a state of the wind power system. 9. The method as claimed in claim 1 , wherein: modeling the network characteristic includes modeling the network characteristic as at least one first differential equation, and modeling the wind system includes modeling the wind system as at least one second differential equation. 10. The method as claimed in claim 1 , wherein the modeled network and/or at least one simplified modeled network, determined from the at least one modeled linearized working point, is detected or adjusted continuously during operation to respond to changes in a structure of the electrical supply grid. 11. The method as claimed in claim 1 , wherein the wind power system is a wind power installation or a wind farm including a plurality of wind power installations. 12. The method as claimed in claim 1 , wherein the low-frequency oscillations are sub synchronous resonances. 13. The method as claimed in claim 1 , comprising: configuring the wind system controller as a robust controller for variations of the closed control circuit. 14. The method as claimed in claim 1 , comprising: configuring the damping control as multi-variable control; receiving at least one electrical voltage of the electrical supply grid as a first input; outputting, by the wind system controller, at least one electrical output current for feeding into the electrical supply grid; and outputting at least one further variable from a list including: an electrical intermediate circuit voltage of a direct voltage intermediate circuit; a reactive power output by an inverter; an electrical generator power; a speed of an electrical generator; and at least one blade angle of adjustable rotor blades. 15. The method as claimed in claim 5 , wherein damping parameters are varied to produce different working models having different eigenvalues, and wherein a respective damping parameter is selected and used for the damping control of the wind power system depending on the eigenvalues. 16. The method as claimed in claim 9 , wherein: the modeled network characteristic is represented in a nonlinear state space representation, and/or the at least one modeled simplified working point is the modeled network characteristic linearized for a selected operational point, wherein the at least one modeled simplified working point is represented in a linear state space representation. 17. A wind power system, comprising: a closed control circuit configured to provide damping control for damping low-frequency oscillations, wherein the wind power system is configured to: feed electrical power generated from wind into an electrical supply grid; and damp the low-frequency oscillations in the electrical supply grid, wherein the electrical supply grid has a l