Laser tracker with calibration unit for self-calibration

What is claimed is: 1. A laser tracker comprising: a beam source for generating measurement radiation; a base, which defines a standing axis; a support, which defines a tilt axis standing essentially orthogonally to the standing axis, wherein: the support is pivotable by a motor in relation to the base about the standing axis, and a horizontal pivot angle is defined by an alignment of the support in relation to the base; a beam deflection unit, which is pivotable by a motor about the tilt axis in relation to the support, wherein a vertical pivot angle is defined by an alignment of the beam deflection unit in relation to the support, wherein the beam deflection unit is configured for emitting and aligning the measurement radiation and for receiving at least a part of the measurement radiation reflected on a target; angle meters for determining the horizontal pivot angle and the vertical pivot angle; a distance meter for determining a distance to the target; and a photosensitive surface detector for detecting a position of incidence of the reflected measurement radiation on the surface detector and for generating an output signal for aligning the beam deflection unit for tracking the target; wherein the base has a self-calibration unit having: at least one first retroreflective reference target; at least one optical assembly acting as a reduction objective lens; and the self-calibration unit can be targeted using the measurement radiation for determining at least one calibration parameter with respect to a position and/or direction of the measurement radiation for the laser tracker such that an optical beam path of the measurement radiation extends through the optical assembly and the measurement radiation is incident on the at least first retroreflective reference target, wherein: a first calibration measurement can be carried out using a distance, which is simulated with respect to relevant measured variables for the determination of the at least one calibration parameter, to the at least first retroreflective reference target; and the simulated distance is greater than an actually structurally provided distance to the at least first retroreflective reference target. 2. The laser tracker as claimed in claim 1 , wherein: the relevant measured variables are represented by the horizontal pivot angle, the vertical pivot angle, and/or the position of incidence on the photosensitive surface detector. 3. The laser tracker as claimed in claim 1 , wherein: the at least one calibration parameter specifies: a servo-monitoring point on the position-sensitive surface detector for regulating the alignment of the measurement radiation on the target in the scope of the target tracking and/or; an offset between a target axis defined by a structural implementation of the beam deflection unit and an emission axis defined by the emission of the measurement radiation; and/or a target axis error which specifies an angle offset between the target axis and the emission axis. 4. The laser tracker as claimed in claim 1 , wherein: the optical assembly has at least two optical elements for shaping the measurement radiation, wherein at least one beam cross-sectional area of the measurement radiation can be reduced in size and/or the beam path of the measurement radiation is variable, and/or the optical assembly defines a specific optical imaging scale in the range between 0 and 1. 5. The laser tracker as claimed in claim 3 , wherein: the optical elements comprise diffractive optical elements. 6. The laser tracker as claimed in claim 1 , wherein: at least one second calibration measurement using at least one further distance is provided in that the self-calibration unit: has a second retroreflective reference target, which can be targeted using the measurement radiation; and/or has a positioning unit implemented such that: the optical assembly can be positioned in a defined manner in relation to the at least first and/or second retroreflective reference target; and/or the at least first and/or second retroreflective reference target can be positioned in a defined manner in relation to the optical assembly; wherein the at least one further distance differs from a simulated distance. 7. The laser tracker as claimed in claim 6 , wherein: the optical assembly can be positioned in a defined manner comprising at least one of relatively offset, rotated in a defined manner, and linearly in parallel to the optical beam path. 8. The laser tracker as claimed in claim 6 , wherein: the at least first and/or second retroreflective reference target can be positioned offset linearly in parallel to the optical beam path. 9. The laser tracker as claimed in claim 6 , wherein: the simulated distance can be generated by means of offsetting the optical assembly and/or the at least first or second retroreflective reference target by means of the positioning unit such that the optical beam path extends through the optical assembly and is incident on the at least first retroreflective reference target; and/or the at least one further distance can be generated by means of offsetting the optical assembly by means of the positioning unit out of the optical beam path such that the measurement radiation extends offset to the optical assembly; and/or the at least one further distance can be generated by means of linear displacement of the at least first or second retroreflective reference target and/or the optical assembly in parallel to the optical beam path. 10. The laser tracker as claimed in claim 1 , wherein: the laser tracker has a control and analysis unit implemented such that a calibration functionality can be executed to determine the at least one calibration parameter, having: an execution of a two-location measurement using the simulated distance and/or using the at least one further distance, wherein, in the scope of the two-location measurement, two measurements are executed in two locations at two different horizontal pivot angles and at two different vertical pivot angles and for each of the two measurements; the measurement radiation is aligned by means of alignment of the beam deflection unit in relation to the base on the reference target, which provides the simulated distance and/or the at least one further distance, of the self-calibration unit; the respective horizontal pivot angle and the respective vertical pivot angle are determined; in each case the position of incidence of the measurement radiation, which is reflected on the respective reference target, on the photosensitive surface detector is determined; a derivation of the at least one calibration parameter in dependence on the determined horizontal pivot angles, vertical pivot angles, and positions of incidence; and wherein the two-location measurement represents the first calibration measurement. 11. The laser tracker as claimed in claim 10 , wherein: the control and analysis unit is implemented such that during execution of one two-location measurement in each case for the simulated distance and the at least one further distance in the scope of the calibration functionality; the servo-monitoring point on the position-sensitive surface detector for regulating the alignment of the measurement radiation on the target in the scope of the target tracking; the offset between the target axis defined by the structural implementation of the beam deflection unit and the emission axis defined by the emission of the measurement radiation; the target axis error, which specifies the angle offset between the target axis and the emission axis; and are determined as calibration parameters. 12. The