Camera system comprising a zoom lens and a linear encoder

What is claimed is: 1. A laser tracker adapted to track a target and comprising a camera system for imaging said target, comprising a zoom lens for use in a surveying device, the camera system comprising: a tubular guide system having a tube body, which defines a tube interior having an interior surface and an optical axis, wherein the tube includes a first guide longitudinal slot, a sensor module, which is arranged downstream from the guide system, having an optical sensor for acquiring optical radiation, at least one first carriage on the tube interior surface, each first carriage comprises an optics carrier holding at least one optical element, an elongate driver coupled with the optics carrier, and a first position encoder element on the optics carrier or on the elongate driver wherein each first carriage is arranged so it is linearly movable in the tube interior along the optical axis by the first driver extending through the first guide longitudinal slot and is mounted by a slide-guided mounting of a sliding element of the first carriage being on the tube interior surface of the tube body, wherein the first carriage is linearly movable essentially without play in a plane through the tube body perpendicular to the optical axis, and a first drive system that is outside the tubular body and coupled to the driver for moving the first carriage along the optical axis, and a first scanning sensor positioned for the acquisition of a position of the first position encoder element such that a position-dependent first scanning signal, which is linked to the linear position of the first carriage, can be generated, so that a linear position of the first carriage is derivable, and wherein the laser tracker is adapted to track the target by means of a measurement laser beam emitted onto a retroreflector of the target and to determine a distance to the target using the measurement laser beam. 2. The laser tracker as claimed in claim 1 , wherein the optics carrier has an outside surface with at least two sliding elements protruding therefrom and in contact with the tube interior for the mounting of the first carriage without play, wherein at least one of the at least two sliding elements is turned for adjustment. 3. The laser tracker as claimed in claim 1 , wherein the first position encoder element is arranged on the optics carrier, wherein the first scanning sensor for acquiring the first position encoder element is positioned at a first acquisition opening of the tube body, and/or is embodied as a glass scale. 4. The laser tracker as claimed in claim 3 , wherein the at least one fixed optical assembly is embodied as: a first fixed optical assembly having at least one optical element, which is attached at the entry of the tube interior, and/or a second fixed optical assembly having at least one optical element, which is attached on the end of the tube interior facing toward the sensor module. 5. The laser tracker as claimed in claim 1 , further comprising at least one fixed optical assembly having in each case at least one optical element, which is arranged in the tube interior along the optical axis. 6. The laser tracker as claimed claim 1 , wherein the first drive system comprises: a first motor, and a first movement transmitting element, wherein the first driver forms a connection between the first movement-transmitting element and the first carriage, the first driver is installed both on the first movement-transmitting element and also on the first carriage. 7. The laser tracker as claimed in claim 6 , wherein the first motor is a direct-current motor. 8. The laser tracker as claimed in claim 7 , wherein: the first position encoder element is arranged on the first driver, and/or the first driver is embodied as the first position encoder element. 9. The laser tracker as claimed in claim 6 , wherein the first driver is perpendicular to the optical axis. 10. The laser tracker as claimed in claim 6 , wherein the first drive system further comprises: a first deflection roller, which is rotatable by the first motor, and which can be pre-tensioned; and a first belt movable by a rotation of the first deflection roller, wherein the first movement-transmitting element is fastened on the first belt. 11. The laser tracker as claimed in claim 6 , wherein the first belt comprises a toothed belt. 12. The laser tracker as claimed in claim 6 , wherein the first driver is part of the first carriage and is connected without play to the optics carrier. 13. The laser tracker as claimed in claim 6 , wherein the first driver is connected via a first ball joint or is operationally linked by means of magnetic attraction forces to the first carriage. 14. The laser tracker as claimed in claim 6 , wherein the first driver is screwed onto the optics carrier. 15. The laser tracker as claimed in claim 1 , wherein the optics carrier comprises aluminum and/or is cylindrical, and/or the optical element comprises a lens or a lens group. 16. The laser tracker as claimed in claim 1 , further comprising: a second carriage, which has an optical assembly having at least one optical element and an optics carrier, is arranged so it is linearly movable in the tube interior along the optical axis, and is mounted essentially without play in a plane through the tube body perpendicular to the optical axis, a second drive system for moving the second carriage along the optical axis, a second position encoder element arranged on the second carriage, and a second scanning sensor for acquiring the second position encoder element such that a position-dependent scanning signal, which is linked to the linear position of the second carriage, can be generated, so that a linear position of the second carriage is derivable. 17. The laser tracker as claimed in claim 1 , wherein the optical sensor is embodied as a CMOS sensor, as a CCD sensor, or as a pixel array sensor. 18. The laser tracker as claimed in claim 1 , wherein the enlargement stage is set in dependence on the distance to the target that is determined using the measurement laser beam. 19. The laser tracker as claimed in claim 1 , wherein the zoom lens has a zoom function, in which an enlargement stage is set in dependence on a distance between the camera system and the target determined by the laser tracker. 20. The laser tracker as claimed in claim 1 , wherein the optics carrier has an outside surface with at least two sliding elements protruding therefrom and in contact with the tube interior. 21. The laser tracker as claimed in claim 1 , wherein the optics carrier has an outside surface with at least three sliding elements located in a plane perpendicular to the optical axis.