Mobile field controller for measurement and remote control

What is claimed is: 1. A mobile field controller for measurement and remote control, configured in such a way that it forms a system for coordinative geodetic determination of the position of target points together with a remote controllable geodetic surveying device having distance and direction measurement functionality, the field controller comprising: a control and evaluation unit with an electronic display for controlling the surveying device remotely and for evaluating and/or transmitting measurement data; a housing that can be hand-held coupled with the control and evaluation unit; a geodetic target object supported by the housing, an absolute target position of which can be determined by the surveying device by means of a direction-based and laser beam-based distance measurement; and a distance-measuring unit for determining the distance between the field controller and at least one target point without contacting the ground, wherein the at least one target point is optically marked by means of the field controller, wherein: a spatial orientation of the field controller can be determined; the geodetic target object and the distance-measuring unit are in a defined spatial reference relationship to an internal reference system of the field controller, and an absolute position of the target point is calculated from the absolute position of the geodetic target object by means of the determined spatial orientation of the field controller and the determined distance between the field controller and the target point. 2. The field controller according to claim 1 , wherein: the control and evaluation unit is configured to: register measurement data for determining the spatial orientation of the field controller; and partly or wholly evaluate the target position of the geodetic target object and the distance between the field controller and the at least one target point. 3. The field controller according to claim 2 wherein: the absolute position of the at least one target point is calculated from the measurement data; the absolute position of the at least one target point is stored and made available to the user by means of an output means of the field controller; and the position data and/or measurement data can be transmitted to external devices. 4. The field controller according to claim 1 wherein: the distance-measuring unit comprises an electrooptic or an electroacoustic distance measuring unit. 5. The field controller according to claim 1 , wherein: the field controller has an inclination sensor and/or an accelerometer configured to determine: at least one alignment angle of the spatial orientation of the field controller; or changes of at least one alignment angle about at least one axis of the spatial orientation of the field controller. 6. The field controller according to claim 1 , further comprising: a unit that can be sighted optically by the surveying device and is configured to be used by the surveying device or the field controller to determine an alignment angle about at least one axis of the spatial orientation of the field. 7. The field controller according to claim 1 , further comprising: a unit that determines a direction of incidence of a laser beam emitted by the surveying device. 8. The field controller according to claim 1 , wherein: the geodetic target object is a retro-reflective prism reflector; and the field controller has an attachment of a defined length, by means of which the prism reflector is supported by the housing. 9. The field controller according to claim 1 , wherein: the distance-measuring unit is embodied as a laser rangefinder, with a laser source for emitting optically visible laser light. 10. The field controller according to claim 1 , wherein: the distance-measuring unit has: a drive unit, which can be guided in a manual or automated manner, for one-axis or two-axes alignment of the measuring direction; and means for determining the measuring direction relative to a zero axis. 11. The field controller according to claim 1 , further comprising: a digital camera that records a digital image of a target point terrain region, which is displayed to the user on the electronic display. 12. The field controller according to claim 11 , wherein: the electronic display is a touch-sensitive display; and at least one target point is selected in a manual or automated manner for determining the position or marking by means of the digital image. 13. The field controller according to claim 1 , wherein: the distance-measuring unit and the control and evaluation unit are configured to register multiple terrain points within a specific contiguous region in the case of a respectively known or synchronously determined measuring direction; the obtained data are stored as 3D point cloud, wherein the distance-measuring unit is included in at least one of: a laser scanner; a range image camera; a stereo camera; or a light-structure 3D scanner. 14. The field controller according to claim 13 , wherein: the 3D data are visualized on the electronic display and at least one point is selected in a manual or automated manner. 15. The field controller according to claim 11 , wherein: algorithms are saved to the control and evaluation unit, wherein the algorithms, when executed: perform an analysis of the digital image and/or of a 3D point cloud in respect of specific geometric properties, to automatically find and/or fit geometric forms; identify or derive, from the analyzed geometric properties, one or more points serving to identify a target point; superimposing the analyzed geometric properties and identified or derived points onto the digital image or onto the visualized 3D point cloud on the electronic display; and performing at least one of: adopting position data of the identified or derived points directly from the measurement data underlying the 3D point cloud; establishing the position data by calculating points of intersection of the fitted geometric forms; and performing a target point distance measurement on the basis of the target point identification. 16. The field controller according to claim 1 , wherein: the control and evaluation unit calculates the absolute position of points of a 3D point cloud from the determined spatial orientation of the field controller, from the target position of the geodetic target object and from position data of the 3D point cloud. 17. The field controller according to claim 1 , wherein: the housing has a joint that can be rotated in one or two planes within a specific angular range and to which the target object is fastened, wherein the joint has one or more absolute or incremental position sensors for measuring the at least one alignment angle relative to a zero axis. 18. The field controller according to claim 1 , wherein: the housing and the reflector or the attachment has fasteners in such a way that reflector or attachment are replaceable; and the attachment has an encoding that establishes the length of the attachment, such that the spatial reference relationship of the reflector to the reference point of the field controller is established automatically by the control and evaluation unit. 19. The field controller according to claim 1 , wherein: the control and evaluation unit is configured in such a way that determining the position of at least one target point can be carried out completely from the location of a target point, the control and evaluation unit having a trigger unit,