Calibration device and calibration method for a laser beam horizontal trueness testing device

What is claimed is: 1. A calibration device for calibration of a laser beam horizontal trueness testing device, the laser beam horizontal trueness testing device comprising: an inherent inclination compensator and a position sensitive detector for detecting an impinging position of a laser beam in dependency of the entry angle of the laser beam with regard to the horizontal, the calibration device comprising: an elongated laser housing with a longitudinal axis, containing a laser source, whereby the alignment of the laser source is such that a laser beam is emittable by the laser source at least roughly in direction of the longitudinal axis, and an elongated support body serving for support of the laser housing, wherein the support body comprises at least three points of support which define a support array with a defined inserted direction for insertion of the laser housing with its longitudinal axis parallel to the inserted direction and the size and shape of the laser housing is matched to the support array in such a way that the laser housing is insertable into the support array in a first face in at least two different rotational positions and in a second opposing face in at least one rotational position with the longitudinal axis as axis of rotation each and each contact area at the points of support in direction orthogonal to the longitudinal axis is punctiform, by which in each face and each rotational position of the laser housing the laser housing rests position-stable and self-centered due to gravity in the support array and the position of the longitudinal axis is equal. 2. The calibration device as claimed in claim 1 , wherein: the laser housing and/or the support body are precision ground, smooth and surface hardened, wherein the laser housing and/or the support body: are made of high-speed steel, glass or ceramics, and/or are single piece units and/or are made of a material with a coefficient of thermal expansion in the range of 0 to 9·10 −6 K −1 , and/or both ends of the laser housing are enclosed by a sleeve each, whereby the sleeves are precision ground, smooth and surface hardened, wherein each sleeve is designed as the race of a bearing or as a fixed ball bearing. 3. The calibration as claimed in claim 1 , wherein: the points of support form lines parallel to the inserted direction wherefore the support body is designed as a block with a v-shaped support array and the laser housing is designed as a straight cylinder or the support body is designed as a u-shaped support array or as two bars parallel to each other and to the inserted direction, and the laser housing is designed as a straight cylinder or a straight prism, and/or the points of support are designed as single points spaced to each other wherefore the support body comprises single spheres providing the points of support. 4. The calibration device as claimed in claim 1 , wherein: the laser source is designed as a line laser and/or the alignment of the laser source is adjustable. 5. The calibration device as claimed in claim 1 , wherein: the laser housing comprises at least one marking on its external surface for indication of at least one rotational position, wherein the laser housing comprises: two, specifically clearly distinguishable, markings indicating two rotational positions which are separated by 180°. 6. The calibration device as claimed in claim 1 , wherein: the laser housing comprises at least one marking on its external surface for indication of at least one rotational position, wherein the laser housing comprises an alignment reticle. 7. The calibration device as claimed in claim 1 , wherein: the support body comprises at each end a stopper plate as limits of the support array in the inserted direction, wherein one stopper plate comprises alignment slots or a single mark for defined alignment of the laser housing to the support array. 8. A calibration method for calibration of a laser beam horizontal trueness testing device, wherein the method is carried out using the calibration device of claim 1 , wherein the method comprises: determining an impinging position of the laser beam of the laser source on the position sensitive detector with the laser housing in at least two different rotational positions of a first face and at least one rotational position of a second opposing face each, resulting in a first, second and at least a third impinging position, and determining calibration parameters representing the point of true horizontality, based on the first, second and third impinging position. 9. The calibration method as claimed in claim 8 , wherein the method further comprises: determining at least two impinging positions of the laser beam with the laser housing in at least two different rotational positions in the second opposing face each, resulting in the third and a fourth impinging position, and determining calibration parameters from an average of the first, second, third and fourth impinging position. 10. The calibration method as claimed in claim 8 , wherein the method further comprises: cancelling out a cone error of the laser source based on two impinging positions of the laser beam with the laser housing in at least two different rotational positions in one face, whereby the rotation angle between the two different rotational positions is known. 11. The calibration method as claimed in claim 8 , wherein the method further comprises: cancelling out a cone error of the laser source based on at least three impinging positions of the laser beam with the laser housing in at least three different rotational positions in one face. 12. The calibration method as claimed in claim 8 , wherein the method further comprises: canceling out a plane error of the laser source based on the impinging positions of the laser beam in the first and second face. 13. The calibration method as claimed in claim 8 , wherein the method further comprises: determining at least one additional impinging position, of the laser beam of the laser source on the position sensitive detector for a known rotational position in azimuthal direction of the laser beam horizontal trueness testing device different to the rotational position underlying at least one other impinging position, and determining calibration parameters representing a yaw angle of the position sensitive detector, based on the additional impinging position. 14. The calibration method as claimed in claim 8 , wherein the method further comprises: a pre-step before determining a first impinging position, the pre-step comprising orienting the laser beam to the previously defined center of the position sensitive detector. 15. The method as claimed in claim 8 for a calibration device with a line laser as a laser source according to claim 4 , wherein: the rotation angle between two different rotational positions of the laser housing is determined based on the orientation of the laser line on the position sensitive detector in each rotational position. 16. Computer program product having program code which is stored on a machine-readable carrier, for controlling and carrying out the method for calibration according to claim 8 . 17. A system comprising a calibration device as and non-transitory computer program product configured to execute the method according to claim 8 . 18. The system as claimed in claim 17 , wherein: the system further comprises a laser beam horizontal trueness testing device, wherein the laser beam horizontal trueness testing device comprises