Combination device and optical system

The invention claimed is: 1 . A combination device, comprising: at least two inputs, each input for entry of a respective input beam of at least two input beams, and one or more outputs, each output for exit of a respective output beam, wherein the combination device is configured to form the respective output beam through a coherent combination of two input beams of the at least two input beams by collinear superposition of the two input beams, wherein the combination device is configured to set a polarization direction of the respective output beam based on a relative phase position of individual phases of the two input beams from which the respective output beam is formed through the coherent combination. 2 . The combination device as claimed in claim 1 , wherein the at least two inputs comprise exactly two inputs, and the one or more outputs comprise only one output, the combination device further comprising: a polarization beam splitter for the coherent combination of the two input beams entering at the two inputs to form the output beam, and a phase shift element arranged downstream of the polarization beam splitter in a beam path, for generating a linear polarization of the output beam. 3 . The combination device as claimed in claim 1 , wherein the at least two inputs comprise exactly two inputs, and the one or more outputs comprise only one output, the combination device further comprising: an interferometer having a first beam channel for propagating a first partial beam and a second beam channel for propagating a second partial beam, wherein the interferometer comprises: a splitting element for splitting the two input beams into the first partial beam and the second partial beam, a combination element for coherently combining the first partial beam and the second partial beam to form the output beam, and at least one polarization-influencing device for influencing, in a fixedly prescribed manner, a polarization direction of at least one of the first partial beam and the second partial beam. 4 . The combination device as claimed in claim 1 , wherein the at least two inputs comprise more than two inputs, and the one or more outputs comprise a plurality of outputs, and the combination device is configured to form a respective output beam exiting at a respective output through a coherent combination of in each case two of the input beams entering at the more than two inputs. 5 . The combination device as claimed in claim 4 , wherein a number of inputs is twice as great as a number of outputs, and the combination device is configured to combine in each case two of the input beams entering at the inputs coherently to form a respective output beam. 6 . The combination device as claimed in claim 5 , further comprising: a polarization beam splitter for coherently combining in each case two of the input beams entering at the inputs to form the respective output beam, wherein the polarization beam splitter is common to all input beams, and, a phase shift element for generating a linear polarization of the respective output beam, wherein the phase shift element is arranged downstream of the polarization beam splitter in a beam path and is common to all output beams. 7 . The combination device as claimed in claim 6 , being configured to supply in each case the two of the input beams that are to be combined to the polarization beam splitter, wherein the two of the input beams have two mutually perpendicular polarization directions, the combination device further comprising, upstream of the polarization beam splitter in the beam path, a polarization-rotating device for rotating a polarization direction of in each case one of the two of the input beams that are combined at the polarization beam splitter to form the respective output beam. 8 . The combination device as claimed in claim 4 , further comprising at least one splitting element for splitting a respective input beam into two partial beams, and at least one combination element for coherently combining the two partial beams to form the respective output beam. 9 . The combination device as claimed in claim 8 , wherein a number of inputs is one greater than a number of outputs, and the combination device is configured to coherently combine a number of pairs of partial beams corresponding to the number of outputs to form in each case one of the output beams. 10 . The combination device as claimed in claim 9 , comprising a number of polarization beam splitters corresponding to a number of input beams, wherein each polarization beam splitter serves as one of the at least one splitting element, wherein the number minus one of the polarization beam splitters serves in each case as one of the at least one combination element. 11 . The combination device as claimed in claim 8 , comprising a common polarization beam splitter that serves as the at least one splitting element common to all input beams and/or as the at least one combination element common to all output beams. 12 . The combination device as claimed in claim 8 , comprising: an interferometer that comprises a first beam channel for propagating a respective first sub-partial beam and a second beam channel for propagating a respective second sub-partial beam, wherein the interferometer has a further splitting element for splitting the two partial beams of two different input beams into the first beam channel and the second beam channel, and at least one polarization-influencing device for influencing, in a fixedly prescribed manner, a polarization direction of at least one of the first sub-partial beam and the second sub-partial beam. 13 . The combination device as claimed in claim 12 , being configured to supply in each case the two partial beams of the two different input beams to the further splitting element, wherein the two different input beams are oppositely circularly polarized, wherein the combination device has at least one phase-influencing element for influencing a phase of in each case one of the two partial beams. 14 . An optical system comprising: a beam source for generating a laser beam, a splitting device for splitting the laser beam into at least two coherent input beams, a phase modulation device for modulating a relative phase position of the at least two input beams, and a combination device as claimed in claim 1 for forming at least one output beam through coherent combination of the at least two input beams. 15 . The optical system as claimed in claim 14 , being configured to supply the at least two input beams to the inputs of the combination device with substantially a same power. 16 . The optical system as claimed in claim 14 , being configured to supply the at least two input beams to the inputs of the combination device with linear polarization having a prescribed polarization direction or having circular polarization.