Method of controlling a wind farm

The invention claimed is: 1. A method of feeding electric reactive power into an electrical supply network at a grid connection point using a wind farm including one or more wind turbines, the method comprising: calculating a wind farm reactive power output value to be fed in by the wind farm, wherein: the wind farm feeds a wind farm active power output into the electrical supply network, and the wind farm active power output includes individual plant active power outputs respectively generated by: the one or more wind turbines or the one or more wind turbines and one or more additional power generation plants, and the wind farm feeds a wind farm reactive power output into the electrical supply network, and the wind farm reactive power output includes individual plant reactive power outputs respectively generated by the one or more wind turbines or the one or more wind turbines and the one or more additional power generation plants; and calculating, for each wind turbine of the one or more wind turbines or for each wind turbine of the one or more wind turbines and for each additional power generation plant of the one or more additional power generation plants, an individual plant reactive power output value to be generated by the wind turbine or the additional power generation plant, respectively, wherein: calculating the individual plant reactive power output value includes determining the individual plant reactive power output value for each wind turbine or each additional power generation plant depending on: an individual plant active power output of the respective wind turbine or the respective additional power generation plant; the wind farm reactive power output value to be fed in by the wind farm; and all the individual plant active power outputs generated by: the one or more wind turbines or the one or more wind turbines and the one or more additional power generation plants. 2. The method according to claim 1 , comprising: determining the individual plant reactive power output values and generating the individual plant reactive power outputs such that a sum of all the individual plant reactive power outputs is equal to the wind farm reactive power output. 3. The method according to claim 1 , comprising: determining the individual plant reactive power output as: Q N,S =( P N,A /P G,A )* Q G,S , wherein Q G,S is the wind farm reactive power output value to be fed in, P G,A is the wind farm active power output that is fed in, P N,A is the respective individual plant active power output that is fed, and N is an index representing the wind turbine or the additional power generation plant. 4. The method according to claim 1 , comprising: calculating the individual plant reactive power output value by a central wind farm controller. 5. The method according to claim 1 , comprising: calculating the individual plant reactive power output value depending on the wind farm reactive power output that is fed in. 6. The method according to claim 1 , wherein a ratio of the individual plant reactive power output to the individual plant active power output is the same for each wind turbine or additional power generation plant. 7. The method according to claim 1 , comprising: calculating the individual plant reactive power output value from the wind farm reactive power output value to be fed in using an individual conversion function having: a predeterminable basic value which is specific for each wind turbine or additional power generation plant; and a variable weighting that is specific for each wind turbine or additional power generation plant, wherein the variable weighting is calculated depending on the individual plant active power output of the wind turbine or additional power generation plant. 8. The method according to claim 7 , comprising: calculating the individual plant reactive power output as: Q N,S =k N *G N *Q G,S , wherein Q G,S is the wind farm reactive power output value to be fed, k N is the basic value, G N is the variable weighting, and N is an index of the wind turbine or additional power generation plant. 9. The method according to claim 8 , wherein: each wind turbine and additional power generation plant has a plant rated power (P N,R ); the wind farm has a wind farm rated power (P G,R ) that is a sum of all plant rated powers (P N,R ); and the basic value (k N ) for a respective wind turbine or additional power generation plant is a ratio of the plant rated power (P N,R ) of the respective wind turbine or additional power generation plant to the wind farm rated power (P G,R ). 10. The method according to claim 9 , wherein the variable weighting (G N ) represents a ratio between: a ratio of the respective individual plant active power output (P N,A ) to the wind farm active power output (P G,A ); and a ratio of the plant rated power (P N,R ) to the wind farm rated power (P G,R ). 11. The method according to claim 10 , wherein the variable weighting (G N ) is represented as: G N,0 =( P N,A /P G,A )/( P N,R /P G,R ) where G N =G N,0 , or G N tracks G N,0 using a dynamic function. 12. The method according to claim 10 , wherein G N,0 =(P N,A /P G,A )/(P N,R /P G,R ), and the variable weighting (G N ) tracks G N,0 with a first-order delay behavior. 13. The method according to claim 1 , comprising: in response to a change in the fed-in individual plant active power output and/or in the fed-in wind farm active power output, refraining from adjusting the individual plant reactive power output until a predetermined time lag expires, refraining from adjusting the individual plant reactive power output with an additional application of a dynamic tracking function, or refraining from adjusting the individual plant reactive power output based on a current wind power of the wind farm. 14. The method according to claim 1 , wherein, if at least one individual plant active power output is unavailable for calculating the individual plant reactive power output value to be generated, the individual plant reactive power output value to be generated is determined temporarily for the wind turbine or additional power generation plant from the wind farm reactive power output value to be fed in and by using a predetermined default value. 15. The method according to claim 1 , comprising: calculating the individual plant reactive power output to be generated depending on at least one criterion selected from a list of criteria including: power line losses of the wind farm; a cable factor having, as a weighting factor, a distance of the wind turbine to the grid connection point, or a grid attenuation, or a grid gain of an introduced reactive current; a fixed converter factor that is specified depending on an infeed inverter and which have, as a weighting factor, a predefined converter efficiency; a dynamic converter factor which takes into account detected properties of the infeed inverter; a dynamic converter factor which takes into account a currently detected efficiency of the infeed inverter; an overload factor which takes into account a duration and/or magnitude of an overload; an expected or forecast power output; and a reserve factor which takes into account possible changes in active power generation in order to perform a system service, wherein the individual plant reactive power output value to be generated is reduced compared with an individual plant reactive power output which does not take the reserve factor into account. 16. A wind farm including a plurality of wind