Optical assembly for variably generating a multi-focus profile

What is claimed is: 1. An optical assembly for generating a multi-focus profile from an at least essentially collimated laser beam, the optical assembly comprising: a beam path, passing, in succession, through: a microlens array assembly that includes multiple microlens arrays, wherein each microlens array of the multiple microlens arrays includes a plurality of microlenses having a uniform aperture a, and wherein the microlens array assembly has an effective focal length f ML , and a Fourier lens assembly; and an adjustment mechanism, configured to adjust a mutual optical distance of at least some of the multiple microlens arrays in the beam path, thereby setting the effective focal length f ML of the microlens array assembly, wherein the adjustment mechanism has multiple adjustment positions i=1, . . . , M, i being an adjustment position index and M being a natural number ≥2, wherein, each respective adjustment position i of the multiple adjustment positions satisfies the condition a 2 λ · f ML , i ~ N i , a being the uniform aperture, λ being a center wavelength of the laser beam, f ML,i being the effective focal length f ML of the microlens array assembly set by the respective adjustment position i, and N i being a natural number. 2. The optical assembly as claimed in claim 1 , wherein each of the respective adjustment positions satisfies the condition a 2 λ · f ML , i - N i ≤ 0.2 . 3. The optical assembly as claimed in claim 1 , wherein the beam path passes through at least three microlens arrays. 4. The optical assembly as claimed in claim 1 , wherein the optical assembly comprises at least one optical deflector, and wherein the beam path passes through at least one microlens array component multiple times. 5. The optical assembly as claimed in claim 1 , wherein the adjustment mechanism comprises a slide, on which at least two microlens array components are arranged at a fixed distance, and wherein the slide is movable in relation to at least one further microlens array component along the beam propagation direction (z). 6. The optical assembly as claimed in claim 5 , wherein a first and third microlens array in the beam path are fixed in place and a second and fourth microlens array in the beam path are arranged on the movable slide or vice versa, and wherein, for a focal length f 1 of the first and fourth microlens array and a focal length f 2 of the second and third microlens array, the following applies: f 2 =f 1 /3. 7. The optical assembly as claimed in claim 1 , the optical assembly further comprising a wavelength-dispersive element arranged in the beam path before the microlens array assembly and configured to spectrally expand the at least essentially collimated laser beam in a direction (x) transverse to the beam propagation direction (z), wherein the Fourier lens assembly has a focal length (f FL ) variable in the direction (x) transverse to the beam propagation direction (z). 8. The optical assembly as claimed in claim 7 , wherein the Fourier lens assembly is a free-form lens having a lens curvature variable in the direction (x) transverse to the beam propagation direction (z). 9. The optical assembly as claimed in claim 1 , wherein the adjustment mechanism is motorized and includes an electronic control device, wherein the various adjustment positions i are programmed in the electronic control device and are automatically accessible by means of the electronic control device. 10. The optical assembly as claimed in claim 1 , wherein the optical assembly further comprises a phase shifter, configured to generate, for the laser light, a phase offset of n*π, where n is an odd natural number, between the beam bundles of adjacent microlenses of the microlens arrays. 11. The optical assembly as claimed in claim 10 , wherein the phase shifter is a phase shifter element, in which first passing elements and second passing elements are formed alternately in the direction (x) transverse to the beam propagation direction (z), wherein the passing of a first passing element generates the phase offset of n*π for the laser light in relation to the passing of a second passing element. 12. The optical assembly as claimed in claim 10 , wherein the phase shifter is integrated into one of the microlens arrays, wherein the profiling of the microlens array at the transition of two adjacent microlenses provides a thickness jump in each case, which generates the phase offset of n*π for the laser light. 13. The optical assembly as claimed in claim 1 , wherein the optical assembly furthermore comprises a beam-forming lens, which is arranged in the beam path before the microlens arrays, wherein a focal length f SL of the beam-forming lens satisfies the condition 1 f SL = λ a 2 . 14. The optical assembly as claimed in claim 1 , wherein a lateral offset Δ of at least one of the microlens arrays in relation to at least one other one of the microlens arrays with respect to at least one direction (x, y) transverse to the beam propagation direction (z) is settable using the adjustment mechanism, wherein the adjustment mechanism has multiple lateral adjustment positions j=1, . . . , L, where j is an index of the lateral adjustment positions and L is a natural number ≥2, at which the following applies: Δ j = a 2 * j where Δ j is a lateral offset at the lateral adjustment position j. 15. The optical assembly as claimed in claim 1 , wherein at least two of the microlens arrays in the beam path have a different focal length. 16. The optical assembly as claimed in claim 1 , wherei