Method and device of controlling an operation of a floating wind turbine

The invention claimed is: 1 . A method of controlling an operation of a floating wind turbine, the floating wind turbine comprising a tower, a nacelle rotatably mounted to the tower about a nacelle yaw axis, a hub mounted to the nacelle rotatable about a hub rotational axis, and blades mounted to the hub, wherein the floating wind turbine is floated such that the wind turbine can perform a wind turbine yaw rotation about a wind turbine yaw axis parallel to the nacelle yaw axis, a wind turbine roll rotation about a wind turbine roll axis perpendicular to the wind turbine yaw axis and in parallel to the hub rotational axis, and a wind turbine pitch rotation about a wind turbine pitch axis perpendicular to the wind turbine roll axis and the wind turbine yaw axis; wherein the method controls a parameter of the operation of the floating wind turbine by the following steps: determining a pitch rotation of the wind turbine; determining a roll rotation of the wind turbine; calculating a pitch difference between the pitch rotation and a wind turbine pitch reference; calculating a roll difference between the roll rotation and a wind turbine roll reference; determining a pitch and roll impact value based on the pitch difference and the roll difference, wherein the pitch difference and roll difference remain as separate values through determination of the pitch and roll impact value; determining a reference of the parameter based on a predefined reference of the parameter and the pitch and roll impact value; and controlling the parameter of the wind turbine based on the reference of the parameter. 2 . The method according to claim 1 , wherein the reference of the parameter is a target output power of the wind turbine. 3 . The method according to claim 2 , wherein an output power of the wind turbine is controlled based on the target output power for a speed regulation which minimizes blade pitch angle variations and/or aerodynamic damping variations. 4 . The method according to claim 2 , wherein an output power of the wind turbine is controlled based on the target output power for generating a counter torque to damp the wind turbine roll rotation. 5 . The method according to claim 1 , wherein the reference of the parameter is a target position of an add-on member on at least one of the blades, which add-on member changes an aerodynamic property of the blade. 6 . The method according to claim 5 , wherein the position of the add-on member on the blade is controlled based on the target position of the add-on member on the blade to implement a positive damping into the wind turbine for cancelling a negative damping from a speed-pitch controller and thereby damping wind turbine pitch rotation. 7 . The method according to claim 5 , wherein the position of add-on members on the blades is controlled based on the target position of the add-on members on the blades individually for each blade to implement a counter-torque for damping wind turbine roll rotation. 8 . The method according to claim 1 , wherein the reference of the parameter is a target rotational speed of the hub or a blade pitch angle of the blades. 9 . The method according to claim 1 , wherein: the pitch rotation of the wind turbine is determined based on a tower top acceleration at a top of the tower, which is measured by a G-sensor, the roll rotation of the wind turbine is determined based on the tower top acceleration which is measured by the G-sensor, the pitch rotation and/or the roll rotation is determined from an acceleration in pitch and/or roll coordinates which are measured by the G-sensor, the pitch rotation and/or the roll rotation is determined from a velocity in the pitch and/or roll coordinates which are measured by a gyroscope, the pitch rotation and/or the roll rotation is determined from angles in the pitch and/or roll coordinates which are measured by an inclinometer, and/or the pitch rotation and/or the roll rotation is determined from a load on the blade measured by a blade load sensor which measures a load on at least one of the blades. 10 . The method according to claim 1 , wherein the method further includes at least one of the following steps: estimating a natural frequency of the wind turbine roll rotation and/or the wind turbine pitch rotation; and a filtering step to provide a signal-to-noise ratio between a frequency of a wind turbine roll rotation and/or a wind turbine pitch rotation on the one hand, and a frequency of an input sensor signal on the other hand, with a parametrical updating step to verify that the filtering step is targeting an expected frequency. 11 . The method according to claim 1 , wherein the pitch and roll impact value is determined from a lookup-table where values of the pitch difference and the roll difference are stored as arguments. 12 . The method according to claim 1 , wherein the reference of the parameter is determined from a lookup-table where values of the predefined reference and the pitch and roll impact value are stored as arguments. 13 . The method according to claim 1 , wherein the parameter of the wind turbine is controlled for controlling at least one of a speed, an acceleration, and an amplitude of roll and/or pitch motions of the floating wind turbine. 14 . A control device for controlling an operation of a floating wind turbine, the floating wind turbine comprising a tower, a nacelle mounted to the tower rotatable about a nacelle yaw axis, a hub mounted to the nacelle rotatable about a hub rotational axis, and blades mounted to the hub, wherein the wind turbine is floated such that the wind turbine can perform a wind turbine yaw rotation about a wind turbine yaw axis in parallel to the nacelle yaw axis, a wind turbine roll rotation about a wind turbine roll axis perpendicular to the wind turbine yaw axis and in parallel to the hub rotational axis, and a wind turbine pitch rotation about a wind turbine pitch axis perpendicular to the wind turbine roll axis and the wind turbine yaw axis; wherein the control device is configured to control a parameter of the operation of the floating wind turbine by: determining a pitch rotation of the wind turbine; determining a roll rotation of the wind turbine; calculating a pitch difference between the pitch rotation and a wind turbine pitch reference; calculating a roll difference between the roll rotation and a wind turbine roll reference; determining a pitch and roll impact value based on the pitch difference and the roll difference, wherein the pitch difference and roll difference remain as separate values through determination of the pitch and roll impact value; determining a reference of the parameter based on a predefined reference of the parameter and the pitch and roll impact value; and controlling the parameter of the wind turbine based on the reference of the parameter. 15 . The control device according to claim 14 , wherein the reference of the parameter is a target output power of the wind turbine, and wherein the control device is configured: to control an output power of the wind turbine based on the target output power for a speed regulation which minimizes blade pitch angle variations and/or aerodynamic damping variations, and/or to control the output power of the wind turbine on the target output power for generating a counter torque to damp the wind turbine roll rotation. 16 . The method according to claim 1 , wherein the pitch and roll impact value is a control action which is determined by a control algorithm. 17 . The method according to claim 1 , w