Optical arrangement and method for light beam shaping for a light microscope

What is claimed is: 1. An optical arrangement for light beam shaping for a light microscope, comprising a first liquid crystal region or lifting micromirror region with a plurality of independently adjustable liquid crystal elements or mirrors with which a phase of incident light is changeable in a settable manner; a second liquid crystal region or lifting micromirror region with a plurality of independently adjustable liquid crystal elements or mirrors, with which a phase of incident light is changeable in a settable manner; an input-/output-coupling polarization beam splitter to direct incident light of a specific polarization direction in a direction of the liquid crystal regions or lifting micromirror regions; a polarization beam splitter, which is arranged between the input-/output-coupling polarization beam splitter and the liquid crystal regions or lifting micromirror regions such that the polarization beam splitter separates the light coming from the input-/output-coupling polarization beam splitter, depending on a polarization, into a first partial beam, which is directed to the first liquid crystal region or lifting micromirror region, and into a second partial beam, which is directed to the second liquid crystal region or lifting micromirror region; and that the polarization beam splitter combines the two partial beams returning from the liquid crystal regions or lifting micromirror regions and directs them together to the input-/output-coupling polarization beam splitter as an outgoing light beam. 2. The optical arrangement as claimed in claim 1 , wherein the first and second liquid crystal regions or lifting micromirror regions are regions of a liquid crystal matrix or lifting micromirror matrix; and a polarization rotator is arranged between the polarization beam splitter and the first liquid crystal region or lifting micromirror region or between the polarization beam splitter and the second liquid crystal region or lifting micromirror region. 3. The optical arrangement as claimed in claim 1 , further comprising a transparent retardation element which is arranged between the polarization beam splitter and the first liquid crystal region or lifting micromirror region or between the polarization beam splitter and the second liquid crystal region or lifting micromirror region; and wherein the retardation element is designed such that an optical path length from the polarization beam splitter to the first liquid crystal region or lifting micromirror region is equal to an optical path length from the polarization beam splitter to the second liquid crystal region or lifting micromirror region. 4. The optical arrangement as claimed in claim 1 , wherein a beam path from the polarization beam splitter to the first liquid crystal region or lifting micromirror region is designed such that the first partial beam is incident perpendicularly on the first liquid crystal region or lifting micromirror region and travels back to the polarization beam splitter along said beam path from the polarization beam splitter to the first liquid crystal region or lifting micromirror region; a beam path from the polarization beam splitter to the second liquid crystal region or lifting micromirror region is designed such that the second partial beam is incident perpendicularly on the second liquid crystal region or lifting micromirror region and travels back to the polarization beam splitter along said beam path from the polarization beam splitter to the second liquid crystal region or lifting micromirror region. 5. The optical arrangement as claimed in claim 1 , wherein the polarization beam splitter is designed such that the first and second partial beams travel parallel to one another toward the liquid crystal regions or lifting micromirror regions. 6. The optical arrangement as claimed in claim 2 , wherein at least two, or all, of the following components are in direct contact: the polarization beam splitter, the polarization rotator, the liquid crystal matrix or lifting micromirror matrix, and a transparent retardation element. 7. The optical arrangement as claimed in claim 1 , wherein a front polarization rotator is arranged between the input-/output-coupling polarization beam splitter and the polarization beam splitter and is oriented such that light is separated at the polarization beam splitter into the first and second partial beams in equal proportions. 8. The optical arrangement as claimed in claim 1 , wherein a phase retardation by which a phase of incident light is influenced is settable individually for each liquid crystal element or each mirror; the optical arrangement further comprising a control unit for setting a light intensity to be output, the control unit being configured to set a phase difference between a phase retardation that is generated by a liquid crystal element or a mirror of the first liquid crystal region or lifting micromirror region and a phase retardation that is generated by a corresponding liquid crystal element or a corresponding mirror of the second liquid crystal region or lifting micromirror region, wherein: for a maximum light intensity, the phase difference is set to half a light wavelength, or an integer multiple of the light wavelength plus half a light wavelength, as a result of which the outgoing light beam has a polarization direction that is rotated through 90° compared to the incoming light and is therefore not directed at the input-/output-coupling polarization beam splitter in the direction from which the incoming light has come, for a minimum light intensity, the phase difference is set to 0 or an integer multiple of the light wavelength, with the result that the outgoing light beam has the same polarization direction as the incoming light and is thus directed at the input-/output-coupling polarization beam splitter in the direction from which the incoming light has come. 9. The optical arrangement as claimed in claim 1 , wherein a phase retardation by which a phase of incident light is influenced is settable individually for each liquid crystal element or each mirror; further comprising a control unit for setting a phase pattern over a beam cross section, the control unit being configured to set different phase retardations with the liquid crystal elements or mirrors of the same liquid crystal region or lifting micromirror region. 10. The optical arrangement as claimed in claim 9 , wherein for setting an intensity pattern and a phase pattern, the control unit is configured: to set at the liquid crystal elements/mirrors of the first liquid crystal region or lifting micromirror region mutually different phase retardations, which together help form the phase pattern; to set at the liquid crystal elements/mirrors of the second liquid crystal region or lifting micromirror region phase retardations that are composed of: A) phase retardations that correspond to those of the liquid crystal elements/mirrors of the first liquid crystal region or lifting micromirror region for forming the phase pattern; and B) phase differences to the respective phase retardations of the first liquid crystal region or lifting micromirror region for forming the intensity pattern. 11. A light microscope having an optical arrangement as claimed in claim 1 . 12. A method for light beam shaping for a light microscope, comprising phase-modulating light by means of a liquid crystal matrix or lifting micromirror matrix, which has a plurality of independently switchable liquid crystal elements or mirrors; guiding light of a specific polarization direction by means of an input-/output-coupling polarization beam splitter; splitting the l