Method for generating an ablation program, method for ablating a body and means for carrying out said method

The invention claimed is: 1. A computer implemented method of generating an ablation control program to control emission of a pulsed laser energy beam from a laser to accomplish ablation of material from a surface of a body by application of the pulsed laser energy, comprising: predetermining a predetermined desired ablation profile which indicates ablation depth as a function of a location on the surface of the body or which indicates ablation depth as a function of a direction of the laser beam with respect to the body; modifying the predetermined desired ablation profile as a function of a beam profile of the laser beam, the beam profile being a course of intensity or of surface area related energy or fluence of a pulse of laser energy over a beam cross section near the surface of the body, and also as a function of an inclination of the surface of the body to be ablated to create a pre-compensated desired ablation profile that is based on the energy distribution across the beam profile and the inclination of the surface at a respective target location on the surface; and then, generating the ablation control program based on the pre-compensated desired ablation profile following the modification of the predetermined desired ablation profile; wherein the ablation control program comprises at least one of a series of target locations related to the surface of the body or target directions onto or into which the pulsed laser energy beam is to be applied. 2. The method as claimed in claim 1 , wherein generating the ablation control program further comprises determining a preliminary ablation program from the desired ablation profile; using the preliminary ablation program to predict a predicted ablation profile as a function of an energy distribution across the beam profile and of the inclination of the surface; and generating the ablation program to be used using the predicted ablation profile; determining the predicted ablation profile utilizing at least two locations which are spaced apart from each other by one tenth or less than one tenth of the diameter of the laser beam on the surface of the body; using the predicted ablation profile and the predetermined desired ablation profile to determine a pre-compensated desired ablation profile; and generating the ablation program to be used from the pre-compensated desired ablation profile. 3. The method as claimed in claim 2 , further comprising generating the ablation program to be used in an iterative manner such that, in an actual iteration step, a preliminary ablation program is determined from a modified desired ablation profile determined in a preceding iteration step, an actual predicted ablation profile is predicted on the basis of the preliminary ablation program as a function of an energy distribution across the beam profile and of the inclination of the surface, an actual modified desired ablation profile is determined using the actual predicted ablation profile, and the ablation program to be used is generated as a function of the predetermined desired ablation profile and at least one of the modified desired ablation profiles after the last iteration loop. 4. The method as claimed in claim 1 , further comprising using a model by which a course of ablation depth can be predicted for a pulse as a function of the energy distribution across the beam profile or measuring the beam profile to generate the ablation program, the model comprising a representation of an entire volume ablated by the pulse or comprising a local representation of ablation depth as a function of fluence at an ablated location at a resolution greater than the beam cross section. 5. The method as claimed in claim 1 , further comprising: effecting pre-compensation as a function of an ablation property of the material, the property being dependent on the individual body; and/or; effecting pre-compensation as a function of a change in surface and/or material properties expected during and/or as a result of ablation. 6. The method as claimed in claim 1 , wherein generating the ablation program further comprises acquiring topographical data of the surface in addition to the inclination of the surface, wherein the topographical data is acquired by Placido ring methods or devices, strip projection methods or devices or from optical coherence tomography. 7. The method as claimed in claim 1 , wherein the material to be ablated has a water content, and further comprising: measuring the water content of the material; using the measured water content of the material along with the desired ablation profile to generate the ablation program; and guiding the laser beam over the surface during the ablation to be effected based on the ablation program. 8. The method as claimed in claim 7 , wherein generation of the ablation program further comprises taking into account the water content as a function of the location on the surface or as a function of the location in a region to be ablated. 9. The method as claimed in claim 7 , wherein taking into account the water content further comprises utilizing a further model that correlates, for a predetermined region of the material, the influence that pulses of the pulsed laser beam impinging on the predetermined region or on adjacent regions have on the water content of the predetermined region. 10. The method as claimed in claim 7 , further comprising utilizing a model for the water content or change in the water content of the material as a function of at least the number and/or the position of pulses previously emitted onto the same location and/or adjacent locations in order to take the water content into consideration when generating the ablation program. 11. The method as claimed in claim 7 , wherein measuring the water content of the material further comprises measuring a temperature of the surface. 12. The method as claimed in claim 7 , wherein taking into account the water content further comprises determining from the predetermined desired ablation profile a pre-compensated ablation profile as a function of the water content and generating the ablation program from the pre-compensated ablation profile. 13. The method as claimed in claim 12 , wherein determining the pre-compensated ablation profile further comprises utilizing a modification function, said modification function depending explicitly or implicitly on the water content of the material to be ablated and wherein a value of the modification function at a respectively predetermined location depends on a desired ablation depth given by the desired ablation profile at said location. 14. The method as claimed in claim 7 further comprising generating a preliminary ablation program from the desired ablation profile and, to establish the ablation program to be generated as a function of the water content, modifying at least a fluence value implicitly or explicitly given by the preliminary ablation program, or modifying a pulse energy of a pulse to be emitted onto the target location given by the ablation program, the pulse energy being implicitly or explicitly given by the preliminary ablation program, as a function of the water content at the target location and being assigned to the target location as an indication. 15. The method as claimed in claim 7 , wherein in order to consider at least one of the following: the energy distribution across the beam profile, the inclination of the surface, the method further comprises: determining a desired ablation profile, which is pre-compensated with respect to the influences of the energy distribution across beam profile or of the inclination of the surf