Self-propelled construction machine and method for operating a self propelled construction machine

What is claimed is: 1. A self-propelled construction machine comprising: a machine frame supported by a chassis having wheels or crawler tracks, a milling drum arranged on the machine frame for machining the ground, a drive device for driving the wheels or crawler tracks and the milling drum, a lifting device for adjusting the height of the milling drum with respect to the surface of the ground to be machined, a control and processing unit, which is configured in such a way that a particular advance speed (v), at which the construction machine moves in the terrain, a particular milling drum rotational speed (n), at which the milling drum rotates, and a particular height of the milling drum with respect to a surface of the ground to be machined are adjustable such that material is removed from the ground, a variable (Δ) which is characteristic of a milling profile is determined on the basis of a functional relationship between the variable which is characteristic of the milling profile and the advance speed (v) and/or the milling drum rotational speed (n), wherein the variable (Δ) which is characteristic of the milling profile is a correction variable for a specified milling depth (h), the control and processing unit being configured in such a way that, instead of the specified milling depth (h), a value that is corrected using the correction variable is set for the milling depth. 2. The self-propelled construction machine according to claim 1 , wherein the control and processing unit is configured in such a way that the variable (Δ) which is characteristic of the milling profile is determined on the basis of a functional relationship between the variable which is characteristic of the milling profile and a ratio (v/n) of the advance speed (v) to the milling drum rotational speed (n). 3. The self-propelled construction machine according to claim 1 , wherein the correction variable (Δ) is the vertical distance between a point on the milling profile at which the milling depth is a minimum and a point on the milling profile at which the milling depth is a maximum. 4. The self-propelled construction machine according to claim 1 , wherein the control and processing unit is configured in such a way that, in order to correct the milling depth (h), the milling drum is lowered by the magnitude of the correction variable (Δ). 5. The self-propelled construction machine according to claim 1 , wherein the control and processing unit is configured in such a way that the value for the milling depth (h), which value is corrected using the correction variable (Δ), is compared with a specified threshold value, a control signal being generated if the threshold value is exceeded or undershot. 6. The self-propelled construction machine according to claim 5 , wherein an alarm unit connected to the control and processing unit is provided and is designed in such a way that an acoustic and/or optical alarm is emitted when the alarm unit receives the control signal from the control and processing unit. 7. The self-propelled construction machine according to claim 1 , wherein a display unit connected to the control and processing unit is provided, and is formed in such a way that the variable (Δ) which is characteristic of the milling profile or a value derived from the variable which is characteristic of the milling profile is displayed. 8. The self-propelled construction machine according to claim 1 , wherein the control and processing unit is configured in such a way that a current state of wear of one or more milling tools is taken into account when determining the variable (Δ) which is characteristic of the milling profile. 9. The self-propelled construction machine according to claim 8 , further comprising a measurement value sensor configured to automatically record the current state of wear of the one or more milling tools. 10. The self-propelled construction machine according to claim 1 , wherein the control and processing unit is configured in such a way that, in order to set the specified milling depth (h), the milling drum is lowered from a first position, in which a lower edge of a cutting circle of the milling drum is at the level of the surface of the ground, into a second position when the construction machine is stationary such that the lower edge of the cutting circle of the milling drum is at a distance from the level of the surface of the ground that corresponds to the specified milling depth (h), and that after the construction machine sets off, instead of the specified milling depth (h), a value that is corrected using the correction value (Δ) is continuously set for the milling depth. 11. A method for operating a self-propelled construction machine having a milling drum for machining the ground, the height of which drum is adjustable with respect to the ground, a particular advance speed (v), at which the construction machine moves in the terrain, a particular milling drum rotational speed (n), at which the milling drum rotates, and a particular height of the milling drum with respect to a surface of the ground to be machined being adjustable such that material is removed from the ground, the method comprising: determining a variable (Δ) which is characteristic of a milling profile on the basis of a functional relationship between the variable which is characteristic of the milling profile and the advance speed (v) and/or the milling drum rotational speed (n), wherein the variable (Δ) which is characteristic of the milling profile is a correction variable for a predetermined milling depth (h), a value for the milling depth that is corrected using the correction variable being set instead of a specified milling depth (h). 12. The method according to claim 11 , wherein the variable (Δ) which is characteristic of the milling profile is determined on the basis of a functional relationship between the variable which is characteristic of the milling profile and a ratio (v/n) of the advance speed (v) to the milling drum rotational speed (n). 13. The method according to claim 11 , wherein the correction variable (Δ) is the vertical distance between a point on the milling profile at which the milling depth is a minimum and a point on the milling profile at which the milling depth is a maximum. 14. The method according to claim 13 , wherein in order to correct the milling depth, the milling drum is lowered by the magnitude of the correction value (Δ). 15. The method according to claim 11 , wherein in order to set the specified milling depth (h), the milling drum is lowered from a first position, in which a lower edge of a cutting circle of the milling drum is at a level of the surface of the ground, into a second position when the construction machine is stationary such that the lower edge of the cutting circle of the milling drum is at a distance from the level of the surface of the ground that corresponds to the specified milling depth (h), and that after the construction machine sets off, instead of the specified milling depth (h), a value for the milling depth that is corrected using the correction value (Δ) is continuously set. 16. The method according to claim 11 , further comprising: comparing the value for the milling depth (h), which value is corrected using the correction variable (Δ), with a specified threshold value, and generating a control signal if the threshold value is exceeded or undershot. 17. The method according to claim 16 , further comprising emitting an acoustic and/or optical alarm via an alarm unit responsive to the control signal. 18. The method a