Calibration of a coordinate measuring machine using a calibration laser head at the tool centre point

What is claimed is: 1. A calibration method for a coordinate measuring machine, the coordinate measuring machine comprising: a drive mechanism for moving a tool carrier relative to a base for approaching a measurement point; and a calibration laser head implemented so and attached to the tool carrier so that a laser beam, which is emittable by the calibration laser head, is swivelable around at least two basically perpendicular axes and changes in distance are measurable interferometrically by means of the calibration laser head, wherein a set of retro-reflectors is arranged in fixed positions relative to and/or onto the base; the method comprising: emitting and directing the laser beam towards a first of the set of retro-reflectors, whereby a measuring path is defined by the orientation of the laser beam; moving the calibration laser head along the measuring path so that the laser beam is kept directed towards the first retro-reflector according to the measuring path and the reflected laser beam is continuously received at the calibration laser head; measuring the change in distance to the first retroreflector at a plurality of measuring positions along the measuring path, gathering a machine position for each of the plurality of measuring positions, the machine position relating to a position of the tool carrier relative to the base, wherein machine coordinates corresponding to drive positions of the drive mechanism are gathered, and deriving calibration data for the coordinate measuring machine depending on the measured change in distance and the machine position for each of the plurality of measuring positions. 2. The calibration method according to claim 1 , wherein: calculating a compensation map based on the measured change in distance and the machine position for each of the plurality of measuring positions for compensating a position information which is determined for the at least one measurement point, wherein the compensation map provides deriving compensated position values for respective machine positions which are gathered by conducting a measuring mode. 3. The Calibration method according to claim 1 , wherein: an automatic laser aligning functionality is executed, wherein an impinging position of the reflected laser beam on side of the calibration laser head is determined and the position and/or orientation of the calibration laser head is adapted based on the impinging position, wherein the position and/or orientation of the calibration laser head is adapted so that the laser beam impinges on the centre of the respective retro-reflector. 4. The calibration method according to claim 1 , wherein: the measuring path defined by the direction of the laser beam provides a defined offset regarding at least one of the two axes. 5. The calibration method according to claim 1 , wherein: the direction of laser beam is adjusted with respect to three rotatory degrees of freedom. 6. The calibration method according to claim 1 , wherein: the calibration method is performed in a dynamic manner, wherein the steps of measuring the change in distance to the first retro-reflector and gathering the machine position for each of the plurality of measuring positions are performed while moving the calibration laser head or in a static manner, wherein the steps of measuring the change in distance to the first retro-reflector and gathering the machine position for each of the plurality of measuring positions are performed at defined rest positions of the calibration laser head, or in a hybrid manner, wherein the calibration method is performed in the dynamic manner for a first part of the plurality of measuring positions and in the static manner for a second part of the plurality of measuring positions. 7. The calibration method according to claim 1 , wherein: the position of at least one reflector of the set of 15 retro-reflectors is pre-known. 8. The calibration method according to claim 1 , wherein: the calibration method is performed automatically after providing a starting command, wherein the method steps are performed in autonomously controlled manner. 9. The calibration method according to claim 1 , wherein: deriving a set of compensation values for a set of positions within a measuring volume, the measuring volume representing a particular volume inside which a spatial coordinate of the measurement point is determinable as to a design of the coordinate measuring machine, wherein a position information which is determined for the at least one measurement point is compensable by applying respective compensation values, and/or defining a compensation model and/or deriving a compensation equation based on the measured change in distance and the machine position for each of the plurality of measuring positions, wherein the position information which is determined for the measurement point, is fed to the compensation model or is processed using the compensation equation, respectively, and a compensated position information is derived from the compensation model or by applying the compensation equation respectively. 10. The calibration method according to claim 1 , wherein: the calibration laser head is supplied with laser light for emitting the laser beam via an optical fibre which is connected to the calibration laser head, wherein a laser source for generating the laser light is located structurally separated from the coordinate measuring machine and is connected to the optical fibre. 11. The calibration method according to claim 1 wherein: an interferometer is associated with the calibration laser head for providing interferometric measurements of the changes in distance, wherein the interferometer is linked to the calibration laser head by a beam path, and/or the calibration laser head comprises an interferometer for measuring the changes in distance interferometrically and/or the calibration laser head comprises a reference surface providing a reference arm of an interferometer, wherein an interference for measuring the changes in distance is generated by superimposing a reference laser beam of the reference arm and the reflected laser beam, wherein the reference and the reflected laser beam are superimposed externally. 12. The calibration method according to claim 1 wherein: performing the method steps for at least the first and a second or more of the reflectors of the set of retro-reflectors, wherein the calibration data is derived on basis of the measurements of change in distance and the gathered machine position for each of the plurality of measuring positions for the at least first and second or more retroreflectors, and/or performing the method steps repeatedly with directing the laser beam towards the same of the set of retro-reflectors, wherein different measuring paths are defined by respective different orientations of the laser beam, and/or the laser beam being emitted at a tool centre point defined by the arrangement of the calibration laser head to the tool carrier, wherein the tool centre point is defined by a centre of rotation regarding swiveling the calibration laser head, or the laser beam respectively, around the at least two axes. 13. A non-transitory computer product having computer-executable instructions for controlling and executing the method of claim 1 . 14. A coordinate measuring machine for determining position information for at least one measurement point of an object to be measured, comprising: a drive mechanism for moving a tool carrier relative to a base for approaching the measurement point, a position providing unit for providing a machine position according to