Correction of curved projection of a spectrometer slit line

The invention claimed is: 1. A spectrometer comprising: an entry slit configured to receive a one-dimensional image slice of light for spectral analysis along a straight object line shape; a projection optics configured to project a spectrally resolved two-dimensional image of the straight object line shape onto a detector array; and a correction optics disposed in an optical path directly behind the entry slit to receive a parallel principal light rays originating from the entry slit, the correction optics comprising: a cylindrical mirror surface having a curvature around a first cylinder axis in a direction perpendicular to a length of the entry slit for providing a first reflection of the light originating from the entry slit; a collimation compensator configured to counteract a decollimation of parallel principal light rays of the parallel principal light rays caused by the first reflection; and a flat mirror surface extending in a direction parallel to the first cylinder axis for providing a second reflection of the light, wherein the correction optics is configured to provide a warping of a straight object line shape of the entry slit into a curved object line shape from a point of view of the projection optics, wherein the warping provided by the correction optics is configured such that a curvature of the curved object line shape counteracts an otherwise distorting curvature in a projection of the straight object line shape by the projection optics without the correction optics, and wherein the spectrally resolved two-dimensional image comprises a plurality of parallel straight projected line shapes formed by spectrally resolved projections of the straight object line shape. 2. The spectrometer according to claim 1 , wherein the correction optics comprises a monolithic block of material with a set of distinct surfaces, with each one of the set of distinct surfaces forming one of: the cylindrical mirror surface, the collimation compensator, and the flat mirror surface. 3. The spectrometer according to claim 2 , wherein the monolithic block comprises an exit surface, and wherein the exit surface is parallel to a second cylinder axis of a front surface forming the collimation compensator. 4. The spectrometer according to claim 1 , wherein the collimation compensator is configured to re-collimate principal light rays originating from different parts of the entry slit to compensate for the decollimation caused by the light rays reflecting off the cylindrical mirror surface. 5. The spectrometer according to claim 4 , wherein the parallel principal light rays originating from different coordinates along the entry slit intersect with the cylindrical mirror surface at intersection points having different coordinates along the first cylinder axis, wherein a principal first light ray, of the parallel principal light rays, originating from a center of the entry slit travels another distance to a point of intersection with the cylindrical mirror surface compared to a principal second light ray, of the parallel principal light rays, parallel to the principal first light ray, but originating from an edge of the entry slit, and wherein the straight object line shape is reflected as a curved line shape by reflection off the cylindrical mirror surface. 6. The spectrometer according to claim 1 , wherein the cylindrical mirror surface is convex from a point of view of the parallel principal light rays reflected by the cylindrical mirror surface. 7. The spectrometer according to claim 1 , wherein the collimation compensator is disposed in a light path between the entry slit and the cylindrical mirror surface. 8. The spectrometer according to claim 1 , wherein the parallel principal light rays originating from the entry slit remain parallel to the resulting light rays after traversing the correction optics. 9. The spectrometer according to claim 1 , wherein the parallel principal light rays after traversing the correction optics are relatively displaced in direction transverse to a length of the slit as a function of their position along the slit to form a curved object line shape. 10. The spectrometer according to claim 1 , wherein the correction optics is positioned within a distance less than one centimeter from the entry slit. 11. A method for correcting curvature in a projection of a spectrally resolved image of an entry slit by spectrometer onto a detector array, the method comprising: providing a correction optics in an optical path directly behind the entry slit wherein the correction optics comprise: an internal reflection surface forming a cylindrical mirror surface having a curvature around a first cylinder axis; a curved entry surface forming a collimation compensator configured to counteract a decollimation of parallel principal light rays after reflection by the cylindrical mirror surface, wherein the collimation compensator comprises a cylindrical optical surface with its curvature around a second cylinder axis at an angle with respect to the first cylinder axis; a flat mirror surface extending in a direction parallel to the first cylinder axis; and an exit surface parallel to the second cylinder axis; and configuring the correction optics to warp a straight object line shape of the entry slit into a curved object line shape from a point of view of projection optics in the spectrometer between the correction optics and the detector array, wherein the warping of the correction optics is configured such that a curvature of the curved object line shape counteracts an otherwise distorting curvature in the projection of the straight object line shape by the projection optics without the correction optics, and wherein the spectrally resolved two-dimensional image comprises a plurality of parallel straight projected line shapes formed by spectrally resolved projections of the straight object line shape. 12. A spectrometer comprising: an entry slit configured to receive a one-dimensional image slice of light for spectral analysis along a straight object line shape; a projection optics configured to project a spectrally resolved two-dimensional image of the straight object line shape onto a detector array; and a correction optics disposed in an optical path directly behind the entry slit to receive a parallel principal light rays originating from the entry slit, the correction optics comprising: a cylindrical mirror surface having a curvature around a first cylinder axis in a direction perpendicular to a length of the entry slit for providing a first reflection of the light originating from the entry slit; a collimation compensator configured to counteract a decollimation of parallel principal light rays of the parallel principal light rays caused by the first reflection; and a flat mirror surface extending in a direction parallel to the first cylinder axis for providing a second reflection of the light, wherein the collimation compensator is configured to re-collimate principal light rays originating from different parts of the entry slit to compensate for the decollimation caused by the light rays reflecting off the cylindrical mirror surface. 13. The spectrometer according to claim 12 , wherein the parallel principal light rays originating from different coordinates along the entry slit intersect with the cylindrical mirror surface at intersection points having different coordinates along the first cylinder axis, wherein a principal first light ray, of the parallel principal light rays, originating from a center of the entry slit travels another distance to a point of intersection with the cylindrical mirror surface compared to