Surveying system

The invention claimed is: 1. A camera module to be used as part of a surveying system that is adapted to determine positions of a position measuring resource that is mounted on a surveying pole and includes a GNSS-antenna or a retro-reflector, wherein: the camera module is configured to be attached to the surveying pole; and the camera module comprises: at least a first and a second camera, the first camera having first imaging properties and the second camera having second imaging properties different from the first imaging properties. 2. The camera module according to claim 1 , wherein, the first camera being designed so that images with an image resolutions lower than an image resolution of images capturable with the second camera are captured. 3. The camera module according to claim 1 , wherein, the first camera includes a first imaging sensor; the second camera includes a second imaging sensor; and the first imaging sensor provides a lower point-to-point resolution regarding images to be captured compared with the second imaging sensor. 4. The camera module according to claim 1 , wherein, the first camera is designed for capturing images with a higher frame rate compared to the second camera. 5. The camera module according to claim 1 , wherein, the first camera is configured so that image capturing according to a first spectral range is provided; the second camera is configured so that image capturing according to a second spectral range is provided; and the first spectral range differs from the second spectral range in particular wherein the first camera provides image capturing according to an infrared spectral range or provides thermographical images. 6. A surveying subsystem comprising: a camera module; a control and evaluation unit, wherein the surveying subsystem is adapted to be used as part of a surveying system that is adapted to determine positions of a position measuring resource that includes a GNSS-antenna or a retro-reflector; and a hand-carried surveying pole on which the position measuring resource is mounted, wherein: the camera module includes at least two cameras for capturing images, wherein a first of the at least two cameras is designed to capture first images with a lower image resolutions compared to second images capturable with a second of the at least two cameras, the control and evaluation unit having stored thereon a program with program code that, when executed, controls and executes a spatial representation generation functionality in which, when moving along a path through a surrounding: a first series of images of the surrounding is captured with the first camera, the first series comprising an amount of images captured with different poses of the first camera, the poses representing respective positions and orientations of the first camera, and a second series of images of the surrounding is captured in parallel with the second camera, a SLAM-evaluation with a defined algorithm using only the first series of images is performed, wherein a plurality of respectively corresponding image points are identified in each of several sub-groups of images of the first series of images and, based on resection and forward intersection using the plurality of respectively corresponding image points, a reference point field is built up comprising a plurality of reference points of the surrounding, wherein coordinates of the reference points are derived, and the poses for the images are determined, thus providing for a faster data processing within the SLAM-evaluation compared to processing data generated by capturing images with the second camera. 7. The surveying subsystem according to claim 6 , wherein, the control and evaluation unit is configured so that the spatial representation generation functionality is controlled and executed in such a way that based on the determined poses a dense point cloud that includes 3D-positions of points of the surrounding is computed as the spatial representation by forward intersection using images of the second series of images. 8. The surveying suubsystem according to claim 7 , wherein, processing of the point cloud is triggered by a user command. 9. The surveying subsystem according to claim 7 , wherein, the control and evaluation unit is configured so that the spatial representation generation functionality is controlled and executed in such a way, that processing of the point cloud is performed using a defined subset of images of the second series of images, wherein the subset is selectable by a user, thus providing for generating detailed 3D-information for a desired part of the surrounding in comparatively short time. 10. The surveying subsystem according to claim 7 , wherein, the control and evaluation unit is configured so that the spatial representation generation functionality is controlled and executed in such a way, that a dense matching algorithm is executed for providing the point cloud using images of the second series of images. 11. The surveying subsystem according to claim 6 , wherein, the control and evaluation unit is configured so that the spatial representation generation functionality is controlled and executed in such a way, that based on the determined poses, an initial point cloud comprising 3D-positions of points of the surrounding is computed by forward intersection using the images of the first series of images only. 12. The surveying subsystem according to claim 11 , wherein, the control and evaluation unit is configured so that the spatial representation generation functionality is controlled and executed in such a way, that a graphical reproduction is generated for the initial point cloud, the graphical reproduction being displayable by display means of the surveying system, thus providing for a comparatively fast direct feedback to a user about already acquired data, so that the already acquired data can be checked regarding its completeness. 13. The surveying subsystem according to claim 12 , wherein, the control and evaluation unit is configured so that the spatial representation generation functionality is controlled and executed in such a way, that a dense matching algorithm is executed for providing the initial point cloud using the images of the first series of images with lower image resolution, thus providing comparatively fast data processing. 14. The surveying subsystem according to claim 6 , wherein, the control and evaluation unit is configured so that the spatial representation generation functionality is controlled and executed in such a way, that the first camera captures the first images with a higher frame rate compared to capturing the second images by the second camera. 15. A surveying subsystem comprising: a camera module; a control and evaluation unit, wherein the surveying subsystem is adapted to be used as part of a surveying system that is adapted to determine positions of a position measuring resource that includes a GNSS-antenna or a retro-reflector; and a hand-carried surveying pole on which the position measuring resource is mounted, wherein: the camera module includes at least one camera for capturing images, the camera being designed so that different capturing modes regarding capturing images with different resolutions and/or with different frame rates are provided, the control and evaluation unit having stored a program with program code so as to control and execute a spatial representation generation functionality in which: a low-resolution-high-frame-rate mode is provided for high-frequency capturing of images with comparatively low resoluti