Geodetic instruments and methods of operating geodetic instruments

What is claimed is: 1. A total station comprising: a center unit, the center unit comprising: a reflecting optical element mounted in the center unit and rotatable about an axis, wherein: the reflecting optical element is rotatable relative to the central unit; and the rotation of the reflecting optical element determines positions scanned at a surface of a target by the total station in a scanning mode; a radiation source adapted to emit light to be output along an output light beam path from the total station via light reflection against the reflecting optical element; and a receiver adapted to receive light entering the total station along an input light beam path; and an electronic distance measurement (EDM) unit adapted to determine a distance to a position at the target based on a signal representative of light received at the receiver. 2. The total station of claim 1 , wherein the center unit further comprises an optical element arranged in the output light beam path, wherein the reflecting optical element is optically located between the radiation source and the optical element. 3. The total station of claim 2 , wherein the optical element is configured to define a divergence of an angular cone of the output light beam path. 4. The total station of claim 1 , wherein the receiver is adapted to receive light entering the total station along the input light beam path via light reflection against the reflecting optical element. 5. The total station of claim 1 , wherein the center unit is rotatable about the axis, the total station further comprising a control unit adapted to adjust an angular displacement profile of the reflecting optical element relative to an angular displacement profile of the center unit for controlling angular displacement of the output light beam path about the axis. 6. The total station of claim 1 , further comprising: a base; and an alidade mounted on the base for rotation about a vertical axis, wherein the center unit is mounted on the alidade for rotation about a horizontal axis. 7. The total station of claim 6 , further comprising: a first controllable drive for rotating the alidade about the vertical axis; and a second controllable drive for rotating the center unit about the horizontal axis. 8. The total station of claim 6 , wherein: the reflecting optical element is rotatable about the horizontal axis and the vertical axis; and the total station further comprises a control unit adapted to control respective rotations of the center unit, the alidade, and the reflecting optical element for controlling angular displacement of the output light beam path about the horizontal axis and the vertical axis. 9. The total station of claim 1 , wherein the EDM unit is adapted to determine a distance to the target based on time-of-flight measurements or phase-shift measurements. 10. The total station of claim 1 , further comprising at least one of a galvanometer, a piezoelectric actuator, and a magnetostrictive actuator for rotating the reflecting optical element. 11. The total station of claim 1 , wherein the reflecting optical element is a scanning mirror or a scanning prism. 12. A total station comprising: a scanning head comprising: a reflecting optical element mounted in the scanning head and rotatable about an axis, wherein: the reflecting optical element is rotatable relative to a center unit of the total station; and the rotation of the reflecting optical element determines positions scanned at a surface of a target by the total station in a scanning mode; a radiation source adapted to emit light to be output from the total station within a transmitting optical channel via reflection against the reflecting optical element; and a receiver adapted to receive light entering the total station within a receiving optical channel; and an electronic distance measurement (EDM) unit adapted to determine a distance to a position at the target based on a signal representative of light received at the receiver. 13. The total station of claim 12 , wherein: the scanning head further comprises an optical element arranged in an output light beam path of the total station; and the reflecting optical element is optically located between the radiation source and the optical element. 14. The total station of claim 13 , wherein the optical element is configured to define a divergence of an angular cone of the transmitting optical channel. 15. The total station of claim 12 , wherein the receiver is adapted to receive, via light reflection against the reflecting optical element, light entering the total station within the receiving optical channel. 16. The total station of claim 12 , wherein: the scanning head is rotatable about the axis; the total station further comprises a control unit adapted to adjust an angular displacement profile of the reflecting optical element relative to an angular displacement profile of the scanning head for controlling angular displacement about the axis of light output by the total station. 17. The total station of claim 12 , further comprising: a base; and an alidade mounted on the base for rotation about a vertical axis, wherein the scanning head is mounted on the alidade for rotation about a horizontal axis. 18. The total station of claim 17 , further comprising: a first controllable drive for rotating the alidade about the vertical axis; and a second controllable drive for rotating the scanning head unit about the horizontal axis. 19. The total station of claim 17 , wherein: the reflecting optical element is rotatable about the horizontal axis and the vertical axis; and the total station further comprises a control unit adapted to control respective rotations of the scanning head, the alidade, and the reflecting optical element for controlling angular displacement, about the horizontal axis and the vertical axis, of light output by the total station. 20. The total station of claim 12 , wherein the reflecting optical element is a scanning mirror or a scanning prism.