Wind park power oscillation control

The invention claimed is: 1 . A method of controlling power oscillations at a point of common coupling in a wind park comprising multiple wind turbines, the method comprising: receiving, from respective wind turbine controllers of the multiple wind turbines, individual power reference offsets, each individual power reference offset defining an adjustment to a wind turbine power reference signal for counteracting mechanical oscillations in the respective wind turbines, based on the individual power reference offsets, determining an aggregated power reference offset, based on the aggregated power reference offset, determining a total power oscillation compensation signal, based on the individual power reference offsets and the total power oscillation compensation signal, determining individual power oscillation compensation signals for adjusting the wind turbine power reference signal of the respective wind turbines, and sending the individual power oscillation compensation signals to the wind turbine controllers of the respective wind turbines. 2 . The method of controlling power oscillations as claimed in claim 1 , wherein the determining the individual power oscillation compensation signals comprises assigning a weighting factor to each wind turbine based on the respective individual power reference offset and determining the individual power oscillation compensation signal based on the weighting factor and the total power oscillation compensation signal. 3 . The method of controlling power oscillations as claimed in claim 2 , wherein the weighting factor depends on at least one of: a phase difference between the individual power reference offset and the total power oscillation compensation signal, an amplitude of the individual power reference offset, a predetermined maximum power modulation amplitude of the respective wind turbine, and a mechanical load history of the respective wind turbine. 4 . The method of controlling power oscillations as claimed in claim 3 , wherein the weighting factor is non-zero only for wind turbines for which the amplitude of the individual power reference offset is below an activation threshold. 5 . The method of controlling power oscillations as claimed in claim 3 , wherein the weighting factor is non-zero for each wind turbine for which the amplitude of the individual power reference offset is below an activation threshold, and wherein the determining the individual power oscillation compensation signals comprises: determining the individual power oscillation compensation signal for each wind turbine for which the amplitude of the individual power reference offset is below the activation threshold, and if a sum of the individual power oscillation compensation signals for all wind turbines for which the amplitude of the individual power reference offset is below the activation threshold is below the total power oscillation compensation signal, assigning non-zero weighting factors to wind turbines for which the amplitude of the individual power reference offset is above the activation threshold. 6 . The method of controlling power oscillations as claimed in claim 1 , wherein the determining the total power oscillation compensation signal comprises deducting an oscillation amplitude threshold from the aggregated power reference offset, the oscillation amplitude threshold representing a predetermined maximum acceptable total power adjustment for counteracting mechanical oscillations in the wind turbines of the wind park. 7 . The method of controlling power oscillations as claimed in claim 1 , wherein the determining the total power oscillation compensation signal comprises time shifting the aggregated power reference offset. 8 . The method of controlling power oscillations as claimed in claim 1 , further comprising temporarily attenuating the total power oscillation compensation signal. 9 . The method of controlling power oscillations as claimed in claim 8 , wherein the temporarily attenuating the total power oscillation compensation signal comprises resetting a timer of a time-dependent attenuation function, the time-dependent attenuation function gradually or stepwise evolving from a maximum attenuation factor to a minimum attenuation factor. 10 . The method of controlling power oscillations as claimed in claim 1 , wherein the individual power reference offsets result from a side-side tower damping algorithm. 11 . A controller for controlling power oscillations at a point of common coupling of multiple wind turbines in a wind park, the controller being operatively coupled to respective wind turbine controllers of the multiple wind turbines and configured to perform an operation, comprising: receiving, from respective wind turbine controllers of the multiple wind turbines, individual power reference offsets, each individual power reference offset defining an adjustment to a wind turbine power reference signal for counteracting mechanical oscillations in the respective wind turbines, based on the individual power reference offsets, determining an aggregated power reference offset, based on the aggregated power reference offset, determining a total power oscillation compensation signal, based on the individual power reference offsets and the total power oscillation compensation signal, determining individual power oscillation compensation signals for adjusting the wind turbine power reference signal of the respective wind turbines, and sending the individual power oscillation compensation signals to the wind turbine controllers of the respective wind turbines. 12 . The controller of claim 11 , wherein the determining the individual power oscillation compensation signals comprises assigning a weighting factor to each wind turbine based on the respective individual power reference offset and determining the individual power oscillation compensation signal based on the weighting factor and the total power oscillation compensation signal. 13 . The controller of claim 12 , wherein the weighting factor depends on at least one of: a phase difference between the individual power reference offset and the total power oscillation compensation signal, an amplitude of the individual power reference offset, a predetermined maximum power modulation amplitude of the respective wind turbine, and a mechanical load history of the respective wind turbine. 14 . The controller of claim 13 , wherein the weighting factor is non-zero only for wind turbines for which the amplitude of the individual power reference offset is below an activation threshold. 15 . The controller as claimed in claim 11 , wherein the determining the total power oscillation compensation signal comprises time shifting the aggregated power reference offset. 16 . A non-transitory computer readable medium storing instructions which, when executed by a computer, cause the computer to perform an operation for controlling power oscillations at a point of common coupling of multiple wind turbines in a wind park, the operation comprising: receiving, from respective wind turbine controllers of the multiple wind turbines, individual power reference offsets, each individual power reference offset defining an adjustment to a wind turbine power reference signal for counteracting mechanical oscillations in the respective wind turbines, based on the individual power reference offsets, determining an aggregated power reference offset, based on the aggregated power reference offset, determining a total power oscillation compensation signal, based on the individual power reference offs