Method of actively counteracting displacement forces with a probing unit

What is claimed is: 1. A method for compensating a force at a probe element of a probing unit, the probing unit being attached to a coordinate measuring machine and moved along a defined moving path with a number of moving points by the coordinate measuring machine for approaching a measuring point at an object, wherein the probing unit comprises an actuator which is arranged and designed in such manner that a counterforce is applicable to the probe element with respect to at least one actuating direction in variable and defined manner, the counterforce depending on an applied actuating signal, wherein the method comprises: receiving movement information about an expected and/or measured movement of the probing unit, the movement information provides information about a force affecting the probe element due to movement of the probing unit, deriving a force parameter for at least one particular moving point based on the movement information, determining the actuating signal for the at least one particular moving point based on the derived force parameter, the actuating signal provides applying a defined counterforce to the probe element by the actuator regarding the force affecting the probe element at the particular moving point. 2. The method according to claim 1 , wherein: measuring a current at the actuator and, based thereon, deriving a measure for an actual counterforce, wherein the applied current depends on the actuating signal and/or the actuating signal is actualised based on the measured current. 3. The method according to claim 1 , wherein: the movement information provides information about an expected inertial force induced at the probe element by moving the probing unit and/or an expected field force, wherein the expected inertial and/or field force affects a particular displacement force at the probe element relative to the probing unit, the actuating signal is determined so that the resulting counterforce applicable by the actuator correspondingly counteracts the expected inertial and/or field force, and the actuating signal is provided to the actuator so that the particular displacement force at the probe element is compensated, wherein the actuating signal is provided as an offset signal. 4. The method according to claim 3 , wherein the expected inertial force comprises an acceleration, centrifugal force, or a Coriolis force. 5. The method according to claim 3 , wherein the expected field force comprises a gravitational force, an electrostatic force, or a magnetic force. 6. The method according to claim 3 , wherein the particular displacement force occurs at a probe tip. 7. The method according to claim 1 , wherein: the movement information provides information about dynamical effects induced at the probe element by moving the probing unit and the actuating signal is determined and provided to the actuator based on the movement information or the force parameter so that the dynamical effects are damped. 8. The method according to claim 1 , wherein: the force parameter is derived by computing at least one particular expected displacement of the probe element or the force affecting the probe element for the at least one particular moving point based on the movement information and/or determining at least one particular expected or measured displacement of the probe element or the force affecting the probe element using a look-up table, the look-up table providing a correlation between an expected and/or measured movement of the probing unit and the induced force. 9. The method according to claim 1 , wherein: providing the actuating signal to the actuator, in case of the movement information providing information about the expected movement of the probing unit, before the probing unit reaches the particular moving point, and/or in case of the movement information providing information about the measured movement of the probing unit, on or after the probing unit reaches the particular moving point. 10. The method according to claim 1 , wherein: a first component of the induced force affecting the probe element referring to a first direction is compensated due to application of a defined counterforce in actuating direction by setting the actuating signal, the first direction being at least substantially parallel to the actuating direction. 11. The method according to claim 1 , wherein: deriving acceleration and/or velocity values referring to the moved probe element, and setting the actuating signal based on the acceleration and/or velocity values. 12. The method according to claim 1 , wherein: continuously actualising the actuating signal depending on the movement information for particular moving points so that respective counterforces as to the induced forces for the particular moving points are applicable to the probe element, and/or setting the actuating signal based on the movement information such that an expected displacement of the probe element which is induced by moving the probing unit is compensated with reference to a defined set-point, wherein a probe tip remains within a defined tolerance zone around the set-point. 13. The method according to claim 1 , wherein: the movement information is based on a part program providing a measuring path the probing unit is to be moved along and/or a given moving trajectory and/or an encoding unit at the coordinate measuring machine providing moving information of a machine component, and/or a model representing a structural design and a mechanical behaviour of the coordinate measuring machine and/or the probing unit, and/or the movement information provides information for the moving points of the expected movement about position movement velocity, occurring accelerations, inertial forces and/or touching forces. 14. A non-transitory computer program product having computer-executable instructions for performing and respectively controlling the method of one of claim 1 . 15. A probing system for a coordinate measuring machine, the probing system comprising: a probing unit with a probe element; and an actuator which is arranged and designed in such manner that a force is applicable to the probe element with respect to at least one actuating direction in variable manner, the force depending on an applied actuating signal, a controlling and processing unit for controlling movement of the probing unit along a defined moving path with a number of moving points, and providing the actuating signal for controlling the actuator, wherein: the controlling and processing unit is adapted to receive movement information about an expected and/or measured movement of the probing unit, the movement information provides information about a force affecting the probe element due to movement of the probing unit, derive a force parameter for at least one particular moving point based on the movement information and determine the actuating signal for the at least one particular moving point based on the force parameter, the actuating signal provides applying a defined counterforce to the probe element by the actuator at the particular moving point regarding the force affecting the probe element, wherein the actuating signal is provided to the actuator. 16. The probing system according to claim 15 , wherein the actuating signal is provided to the actuator before the probing unit reaches the particular moving point on moving along the moving path. 17. The probing system according to claim 15 , wherein the actuating signal is provided to the actuator for counteracting a