Targeted adjusting of the contour using corresponding specifications

The invention claimed is: 1. An operating method for a rolling line wherein the rolling line comprises a number of roll stands for rolling a flat rolling material, the method comprising: providing a control system operable for controlling the rolling line; prior to the rolling of the flat rolling material in the rolling line, the control system of the rolling line receiving actual variables (I) of the flat rolling material before the rolling of the flat rolling material in the rolling line and receiving target variables (Z) of the flat rolling material after the rolling of the flat rolling material in the rolling line, where the target variables (Z) comprise a plurality of discrete characteristic variables that define a contour (K) of the flat rolling material, the discrete characteristic variables comprising at least a profile value (K 1 ), and at least one edge value (K 2 , K 2 ′, K 2 ″) for a thick edge, or at least one dogbone value (K 3 , K 3 ′, K 3 ″) for a dogbone, or at least one edge drop value (K 4 , K 4 ′, K 4 ″) for an edge drop, or at least one taper value (K 5 ) for a thickness taper; prior to the rolling of the flat rolling material in the rolling line, the control system determining desired values (S*) for control variables (S) for the roll stands of the rolling line, based on the actual variables (I) of the flat rolling material and the target variables (Z) of the flat rolling material, in combination with a description (B) of the rolling line which uses a model of the rolling line; the control system determining the desired values (S*) for the control variables (S) in such a way that expected variables (E 1 ) for the flat rolling material after the rolling of the flat rolling material in the rolling line are aligned as much as possible with the target variables (Z); the control system transferring the desired values (S*) to the roll stands of the rolling line, such that the flat rolling material will be rolled in the rolling line according to the transferred desired values (S*); rolling the flat rolling material in the rolling line using the transferred desired values (S*); the control system capturing values of the control variables (S) during rolling the flat rolling material; after the rolling of the flat rolling material, the control system capturing, or determining contour (K) of the rolled material on the basis of the captured control variables (S); after the rolling of the flat rolling material, determining at least one discrete characteristic variable (K 1 to K 5 , K 2 ′ to K 4 ′, K 2 ″ to K 4 ″) for the rolled material from the captured or determined contour (K) of the rolled material; the control system re-determining expected variables (E 2 ) based on the actual variables (I) of the flat rolling material and the captured control variables (S) by using the model of the rolling line for the flat rolling material; the control system comparing the re-determined expected variables (E 2 ) with the at least one discrete characteristic variable (K 1 to K 5 , K 2 ′ to K 4 ′, K 2 ″ to K 4 ″) defining the captured or determined contour of the rolled material; and the control system correcting the model of the rolling line on the basis of the comparison. 2. The operating method as claimed in claim 1 , further comprising: during the rolling of the flat rolling material, the control system capturing or determining on the basis of captured variables, the at least one discrete characteristic variable (K 1 to K 5 , K 2 ′ to K 4 ′, K 2 ″ to K 4 ″) for previously rolled sections of the flat rolling material; the control system comparing the at least one discrete characteristic variable (K 1 to K 5 , K 2 ′ to K 4 ′, K 2 ″ to K 4 ″) with the target variables (Z); and the control system correcting the desired values (S*) for the control variables (S) for the roll stands on the basis of the comparison. 3. The operating method as claimed in claim 1 , further comprising: the control system determining the desired values (S*) for the control variables (S) by optimizing a cost function (F), into which is entered a deviation of the expected variables (E 1 ) for the flat rolling material after the rolling of the flat rolling material in the rolling line from the target variables (Z) of the flat rolling material. 4. The operating method as claimed in claim 3 , further comprising: when determining the desired values (S*) for the control variables (S), the control system taking into consideration limitations of the control elements which also are to be met during the operation of the rolling line. 5. A computer program product comprising a non-transitory computer program which can be executed by a control system for a rolling line for rolling a flat rolling material, wherein the execution of the machine code by the control system causes the control system to operate the rolling line in accordance with an operating method as claimed in claim 1 . 6. A control system for a rolling line for rolling a flat rolling material, wherein the control system comprises a software-programmable control system and is programmed by a non-transitory computer program comprising machine code which can be executed by a control system for a rolling line for rolling a flat rolling material, wherein the execution of the machine code by the control system causes the control system to operate the rolling line, such that the system operates the rolling line in accordance with an operating method as claimed in claim 1 . 7. A rolling line for rolling a flat rolling material, wherein the rolling line has a plurality of the roll stands by means of which the flat rolling material is rolled; and the rolling line has a control system as claimed in claim 6 . 8. The operating method as claimed in claim 1 , wherein the at least one edge value is derived from a difference between a respective maximum thickness of the flat rolling material and a respective minimum thickness of the flat rolling material, wherein the at least one dogbone value is determined by subtracting a center thickness of the flat rolling material from the maximum thickness of the flat rolling material, wherein the at least one edge drop value is derived from the difference between the thickness of the flat rolling material at a respective inner point and the thickness of the flat rolling material at a respective outer point, and wherein at least one taper value is a measure of the asymmetry of the flat rolling material.