DE102013114748A1 - Pumping Opt with increased number of passes - Google Patents

Abstract

The invention relates to a pumping light arrangement (1) comprising a solid-state disk (2) having a laser-active medium, an excitation source (3) for generating a pump radiation field (4) for exciting the laser-active medium, a beam field guidance system (5) for forming a plurality of different types into the solid-state disk ( 2) incident branches (6) of the pump radiation field (4) with at least one reflection optics (7) with reflection areas (8) for the incident and after passing through the solid state disk (2) on a reflective layer (9) reflected, failing branches (6) of the Pump radiation field (4), and a plurality of deflection optics (10) for coupling at least one from the solid disk (2) failing branch (6) to a solid disk (2) incident branch (6) and a coupling optics (12) for guiding the pump radiation field (4) into the beam field guiding system (5). The pumping light arrangement is characterized in that the coupling-in optics (12) when coupling the pumping radiation field (4) into the beam field guiding system (5) for generating a Einkopplungsfokus (13) is formed the coupling optics when coupling the pumping radiation field in the beam field guidance system for generating a Einkopplungsfokus is formed ,

Description

The invention relates to a pumping light arrangement comprising a solid-state disk having a laser-active medium, an excitation source for generating a pumping radiation field for exciting the laser-active medium, a beam field guidance system for forming a plurality of different branches of the pumping radiation field incident into the solid-state disk with at least one reflection optical system with reflection areas for the incident and the after Enforcing the solid-state disk on a reflection layer reflected, failing branches of the pump radiation field, as well as several deflection optics for coupling at least one falling out of the solid disk branch to an incident in the solid disk branch and a coupling optics for guiding the pump radiation field in the beam field guidance system.

Such pumping light arrangements serve to increase the absorption of the pumping light radiation field necessary in the solid-state disk. To reduce thermal aberrations, it is advantageous to reduce the thickness of the solid state disk. Since the absorption decreases with constant doping of the solid-state disk with the laser-active medium, it makes sense to increase the number of passes of the pumped light radiation field through the solid-state disk.

Such a pumping light arrangement is disclosed in the publication DE 10 2011 004 204 A1 described. There, the beam field guidance system is designed such that it focuses the pumping light radiation field on the solid disk, wherein the number of passes through the solid disk is increased by increasing the reflection surface on the reflection optics in the radial direction when using multiple ring areas.

The pumping light arrangement described there has the disadvantage that additional costs and, in addition, imaging errors arise as a result of the magnification of the reflection optics.

The invention has for its object to provide a pumping light arrangement, with the number of passes through the solid state disk is made possible with the same size of the reflection optics, so as to avoid the aforementioned aforementioned aberrations and to reduce costs.

The object is achieved by a pumping light arrangement according to the preamble of claim 1, which is characterized in that the coupling-in optics is formed when the pump radiation field is coupled into the beam field guidance system for generating a coupling-in focus.

Expediently, the beam field guidance system further comprises at least one deflection optics, which is arranged in the region of an intermediate focus in one of the mutually coupled incoming and outgoing branches.

Such a deflection optics is referred to below as Zwischenfokusumlenkoptik.

By "in the region of a focus" (coupling focus or intermediate focus) is meant according to the invention an arrangement in which the distance between the center of the active region of the deflection optics over which the deflection of the branch takes place, and the focus center, ie the intersection between the central axis of the branch and the respective focal plane is smaller than the Rayleigh length of the corresponding branch.

It is particularly favorable, if the distance is smaller than the diameter of the reflection regions of the incoming and / or falling branches on the reflection optics, even more favorable if the distance corresponds to just half the focus diameter.

The additional intermediate focus, in whose area the Zwischenfokusumlenkoptik is arranged, results for example by a "4f-arrangement", the reflection optics having a refractive power with a focal length of size "f" and the solid state disk at a distance "f" is spaced therefrom ,

Expediently, the distance between the intermediate focus realized by the coupling optics is approximately "f" from the reflection optics. The distance of the intermediate focus from the reflective optics along a branch is then also "f". Any existing aberrations or an existing refractive power of the solid disk can lead to a deviation from the distance "f". Likewise, the position of the intermediate focus can be realized by setting a distance deviating from "f" between the coupling focus and the reflection optics.

The various incident and failing branches reflected by the reflection optics, which are respectively converted into one another by the deflection optics, have taken together a total length of approximately "2f". As is usual with a "4f-arrangement", the length of the branches guided over the deflecting optics can be varied differently from the value "2f", e.g. to compensate for an existing refractive power of the solid-state disk or aberrations of the reflection optics.

The Zwischenfokusumlenkoptik, for example, from two arranged at a right angle and almost touching one edge There are deflecting mirrors, wherein the intermediate focus is arranged symmetrically between the mirrors and results in the plane of symmetry as a mirror plane between the deflecting mirrors. Also conceivable is a retroreflector, lens with mirror or an end mirror.

In the case of an end mirror as deflection optics, the failing branch is converted into itself so that it becomes an incident branch after reflection of the pump light radiation field on the end mirror.

Conveniently, the coupling optics and the beam field guidance system are designed such that the coupling focus is arranged in the region of the intermediate focus deflection optics.

This has the advantage that the distance of the central axis of the coupled pump radiation field to the central axis of an adjacent branch formed by the beam field guidance system can be minimized.

In contrast to the pump radiation field with its various branches, which has a finite extension perpendicular to the radiation direction, a single beam centered in the pump radiation field with infinitely small beam radius is referred to here as the "central axis".

It is particularly favorable if the distance between the central axis of the coupled pump radiation field and the central axis of an adjacent branch formed by the beam field guidance system is smaller than the diameter of the reflection regions of the corresponding branches on the reflection optics.

As a result, the reflection areas are superimposed on the reflection optics, thus increasing the density of the branches guided via the reflection optics.

It is particularly favorable if the distance is so small that it just corresponds to the focus diameter of the respective branching or falling branch.

This has the advantage that the branches formed by the beam field guidance system essentially prevail and, at best, are completely separated from one another only in the area of the deflection optics.

Conveniently, the distance between Einkopplungsfokus and reflection optics, and between Zwischenfokusumlenkoptik and reflection optics exactly the same size, at best exactly the same "f".

In order to be able to compensate for any aberrations of the reflection optics or a refractive power of the solid disk, it is also favorable, as already mentioned above, if the distance between reflection optics and at least one other than the intermediate focus deflection optics arranged in the region of the coupling focus is greater or smaller than "f". is.

It is particularly favorable if this intermediate focus deflection optics can be displaced to adjust the distance between the reference optics and the intermediate focus deflecting optics, so that a change in the position of the intermediate focus in the incoming or outgoing branch can be compensated.

In order to be able to minimize the distance between the central axis of the coupled pump radiation field and the central axis of the adjacent branch, which is guided via the intermediate focus deflection optics, in the area of which the coupling focus is located, the beam field guidance system expediently comprises at least one further intermediate focus deflection optics, likewise in the region of Intermediate focus is arranged.

If the coupled pump radiation field and the Zwischenfokusumlenkoptik, in whose area the Einkopplungsfokus is formed, azimuthally (or radially) arranged to each other, then expediently the further Zwischenfokusumlenkoptik transferred from the outgoing beam also in the azimuthal (or radial) direction.

To realize the coupling of incoming and outgoing beam the further Zwischenfokusumlenkoptik is suitably designed so that it has a plane of symmetry, wherein the distance of the central axis of the incoming or outgoing branch to this plane of symmetry is about the same size as the distance between the Central axis of the coupled pump radiation field and the Zwischenfokusumlenkoptik, in the region of the Einkopplungsfokus is arranged.

Expediently, all branches deflected via a respective intermediate focus deflection optics are guided over the same reflection optics.

Particularly in the case of large pump leak diameters, the pump light arrangement described here is favorable because then the difference between the beam field diameter on the reflection optics and the intermediate focus becomes particularly great.

It is particularly favorable if the intermediate focus is smaller than the beam diameter on the solid-state disk, since then the beam diameter on the reflection optics is almost linear with the beam diameter on the solid-state disk increases, but on the other hand, the beam diameter decreases in the intermediate focus.

Conveniently, therefore, the Einkopplungsfokus is smaller than the beam diameter on the solid disk.

It is then also advantageous if the distance of the coupled pump radiation field can be varied to Zwischenfokusumlenkoptik, for example, by a displaceable in this direction pump radiation source and / or coupling optics.

This has the consequence that the distance between the coupling focus and Zwischenfokusumlenkoptik can be reduced with increasing beam diameter on the solid state disk. This results in the advantage that the reflection regions which likewise increase in size on the solid-state disk with increasing beam diameter can be compacted on the reflection optics by an even greater superimposition on the reflective optics which are uniform in terms of area. The pumping light arrangement can thus be designed for a particularly large number of different pumping beam diameters on the solid-state disk.

If the coupled-in branch and the intermediate focus deflection optics, in whose region the coupling focus is formed, are arranged azimuthally (or radially) relative to one another, then it is favorable if all further deflection optics which transfer two branches in the azimuthal (or radial) direction are likewise in the range the respective intermediate focus of the over the deflection optics coupled to each other branches are arranged.

The distance of the central axis of these branches to the plane of symmetry of the deflection optics is then expediently approximately equal to the distance between the central axis of the coupled branch and the deflection optics, in the region of which the coupling focus is arranged.

If the coupled-in branch and the deflection optics, in the region of which the coupling focus is formed, are arranged azimuthally (or radially) relative to one another, it is favorable if there is at least one beam deflection optics which converts a plurality of emergent branches into a plurality of incident branches, in each case via the beam deflection optics coupled to one another and falling branches are arranged exclusively in the radial (or azimuthal) direction.

Expediently, the central axes of at least two branches, which are not coupled to one another via the beam-deflecting optics, then have a smaller distance from each other than the smallest distance between the coupled branches guided via the beam-deflecting optics.

It is particularly favorable if the beam deflection optics is likewise arranged in the region of the intermediate focus of the branches coupled to one another via the beam bending deflection optics and all branch pairs guided by the beam deflection optics are arranged exclusively in an azimuthal (or radial) direction.

Thus, the distances between the incident to the failing branches can also be minimized, so that then all the branches have substantially the same distance from one another to maximize the density of the branches on the reflection optics.

In particular, in this case, it is expedient if all the branches that enter and / or fail in the solid-state disk are guided over exactly one reflection optics.

In principle, however, it is also favorable for all other cases if all the branches that enter and / or fail in the solid-state disk are guided over exactly one reflection optics.

An advantageous embodiment of the pump light assembly according to the invention will be explained with reference to the embodiments illustrated in the drawings.

Show it:

1 a schematic longitudinal section through a pump light assembly according to the invention with a parabolic mirror as a reflection optics,

2 a schematic cross-sectional view of a conventional pumping light arrangement with 24 passes of the pumping radiation field through the solid state disk when reproducing the reflection regions on the reflection optics, jeodch omitting the solid state disk and the exact course of the pump radiation field,

3 a schematic cross-sectional view of a pump light assembly according to the invention with 40 passes of the pump radiation field through the solid state disk, also when reproducing the reflection regions on the reflection optics, omitting the solid state disk and the exact course of the pump radiation field,

4 a schematic cross-sectional view of the pumping light arrangement according to the invention, as already in 3 is shown, but here in the representation of the reflection areas on the deflection prisms or when displaying the Einkoppelfokus,

5 a schematic cross-sectional view of a pump light assembly according to the invention with 40 passes of the pump radiation field through the solid state disk, similar to the 3 and 4 dargestellen embodiment, but with slightly different arrangement of the deflection prisms,

6 a schematic cross-sectional view of another embodiment with numerous arranged in the intermediate focus Strahlbündelumlenkoptiken also with marking the reflection areas on the reflection optics, as well as the deflection prisms, omitting the solid state disk and the exact course of the pump radiation field,

7 a schematic cross-sectional view of a fourth embodiment with 36 passes of the pumping radiation field through the solid disk, in which only individual arranged in Zwischenfokus Zwischenfokusumlenkoptiken are also used with marking the reflection areas on the reflection optics, as well as the reflection areas on the deflection prisms and omitting the solid disk, and the exact Course of the pump radiation field and

8th a schematic cross-sectional view of a fifth embodiment with 60 passes of the pump radiation field through the solid state disk, similar to the embodiment as shown in 5 is shown, however, an additional Zwischenfokusumlenkelement and an enlarged area Umlenkoptik.

In 1 is a schematic longitudinal section through a pump light assembly according to the invention ( 1 ) with a parabolic mirror as reflection optics ( 7 ). The pump radiation field ( 4 ) is generated by the excitation source ( 3 ) and via the coupling optics ( 12 ) into the beam field guidance system ( 5 ) coupled. The coupling optics ( 12 ) a coupling focus ( 13 ) spaced at a distance "f" from the reflection optics ( 7 ) is spaced.

In this embodiment, the injection focus is ( 13 ) smaller than the diameter of the pump radiation field ( 4 ) on the solid state disk ( 2 ).

The coupling focus ( 13 ) is arranged here so that the pump radiation field ( 4 ) just at the Zwischenfokusumlenkelement ( 10 . 11 ) is passed by. Due to the focus here ( 13 ), the intermediate deflecting element ( 10 . 11 ) as close as possible to the injected pump radiation field ( 4 ) arranged.

Due to the "4f" arrangement, which is due to the arrangement of the solid-state disk ( 2 ) in the focus of the parabolic mirror ( 7 ), there is again an intermediate focus ( 15 ) on the formed as an end mirror Zwischenfokusumlenkelement ( 10 . 11 ). The on the Zwischenfokusumlenkelement ( 10 . 11 ) led incoming and outgoing branches ( 6 ) can therefore be at a distance to the coupled pump radiation field ( 4 ), which is smaller than the beam diameter of the pump radiation field ( 4 ) on the reflection optics ( 7 ). This allows a minimization of the distance between the radiation branches with simultaneous local separation of the radiation fields and thus a particularly effective use of the reflection regions ( 8th ) on the reflection optics ( 7 ).

At the in 1 illustrated embodiment, the coupled pump radiation field ( 4 ) through the parabolic mirror ( 7 ) collimates and hits as a collimated incident branch ( 6 ) on the solid state disk ( 2 ), where, after passing through the reflection layer ( 9 ) and again on the parabolic mirror ( 7 ) meets. The pump radiation field ( 4 ) is then from the parabolic mirror on the deflection optics ( 10 . 11 ) focused and spatially shifted again as an incident branch ( 6 ) on the solid state disk ( 2 ) guided.

The here formed by two deflecting Zwischenfokusumlenkoptik ( 10 . 11 ), by deflecting a failing branch ( 6 ) in an incident branch ( 6 ) in the region of their intermediate focus ( 15 ) a minimum distance between the two branches ( 6 ), because the branches ( 6 ) in the area of the intermediate focus ( 15 ) have their smallest extent transverse to the beam direction and thus a spatial separation of the branches ( 6 ) can still be realized even at a small distance.

Any aberrations due to the reflection optics ( 7 ) or by an existing refractive power of the solid-state disk ( 2 ) can be compensated by the distance of the deflecting optics formed by the two deflecting mirrors that deviate from the value of the focal length "f" of the parabolic mirror. In the 1 Therefore, the deflection optics is shown with slightly increased distance.

Formed by the two deflecting Zwischenfokusumlenkoptik in 1 , couples the incoming and outgoing branch ( 6 ) in the radial direction with each other. Likewise, coupled pump radiation field ( 4 ) and designed as end mirror Zwischenfokusumlenkoptik ( 10 . 11 ) arranged in the radial direction.

Other deflecting optics that offset the pump radiation field in the azimuthal direction are not shown here.

In 2 is a schematic cross-sectional view of a conventional pumping light arrangement with 24 passes of the pumping radiation field through the solid state disk showing the reflection areas on the reflection optics, but with the omission of the solid state disk and the exact course of the pump radiation field reproduced. The pump light radiation field is transmitted through the space between the deflecting mirrors ( 10 ) on the reflection optics ( 7 ) guided. The reflection areas ( 8th ) of the pumped radiation field ( 4 ) when passing through the beam field guiding system ( 5 ) consisting of parabolic mirror ( 7 ) and the four deflecting mirrors ( 10 ) is represented by a circle. The order in which the pump light radiation field ( 4 ) at the reflection areas ( 8th ) is represented by a number.

In 3 is a schematic transverse view of a pumping light arrangement according to the invention ( 1 ) with 40 passes of the pump radiation field ( 4 ) through the solid disk ( 2 ), also with representation of the reflection ranges ( 8th ) on the reflection optics ( 7 ), omitting the solid disk ( 2 ) and the exact course of the pump radiation field ( 4 ). The size of the reflection optics ( 7 ) is identical to the one in 2 illustrated conventional pumping light arrangement ( 1 ).

As well as ready in 1 described here, the pumped radiation field ( 4 ) when coupled into the beam field guidance system ( 5 ) focused. The coupling focus ( 13 ) is next to the reflection areas ( 8th ) in 3 played. By arranging a Zwischenfokusumlenkoptik ( 11 ) immediately adjacent to the injection focus ( 13 ), the distance between coupled pump radiation field ( 4 ) and adjacent incoming and outgoing branch ( 6 ) passing over the adjacent intermediate focus tumor ( 11 ) are minimized. The corresponding reflection areas ( 8th ) on the reflection optics ( 7 ) overlap, so that the optical surface of the reflection optics ( 7 ) can be used particularly effectively.

The distance between the incoming and outgoing branches ( 6 ), which are arranged in the radial direction, is ultimately formed by the second Zwischenfokusumlenkoptik formed by two deflecting mirror ( 11 ) realized. This is arranged in such a way that a falling branch reflected from the solid-state disk (FIG. 6 ) is guided on the one of these two deflection mirror. The deflection optics comprising the two deflecting mirrors ( 11 ) is arranged so that its symmetry element, namely the cutting edge between the two deflecting mirrors, a distance from the central axis of the falling branch has, which corresponds exactly to the distance that the coupled pumping radiation field ( 4 ) of the adjacent, designed as end mirror Zwischenfokusumlenkoptik ( 11 ) Has.

4 shows a schematic cross-sectional view of the pumping light arrangement according to the invention, as already in 3 is shown, but here in the representation of the reflection areas on the deflection prisms or in the representation of the coupling focus. Due to the spatial extent of the beam deflection optics ( 10 . 14 ), each having two polygonal (> 4) deflecting mirrors ( 10 . 14 ), the beam diameter of the pumped radiation field ( 4 ) when hitting the deflecting mirror ( 10 . 14 ) of different sizes, so that even areas of reflection adjacent branches partially overlap. But since only azimuthally arranged branches ( 6 ) via these beam deflection optics ( 10 . 14 ) are coupled together, a spatial separation of the radially arranged branches is not necessary.

5 shows a schematic transverse view of a pump light assembly according to the invention with 40 passes of the pump radiation field through the solid state disk, similar to the 3 and 4 dargestellen embodiment, but with slightly different arrangement of Umlenkprismen.

6 again shows a schematic cross-section of another embodiment with numerous arranged in the intermediate focus Strahlbündelumlenkoptiken. Also in this figure, the reflection areas on the reflection optics, as well as the deflection prisms are marked, wherein the solid state disk and also the exact course of the pump radiation field is not shown.

The coupled pump radiation field ( 4 ) and as deflecting mirrors ( 11 ) formed Zwischenfokusumlenkoptik is as well as the incident and ausfallende on the two small deflecting mirrors ( 11 ) formed Zwischenfokusumlenkoptik ( 11 ) guided branch in the radial direction to each other. All others as Strahlbündelumlenkoptik ( 11 . 14 ) formed Umlenkoptiken each pair a ausfallendem and incident branch existing branch pair with each other, wherein the pair of branches is arranged in each case in the azimuthal direction.

All in the 6 shown deflection optics ( 11 . 14 ) are in the area of an intermediate focus ( 15 ) are arranged so that their dimensions corresponding to the smaller beam diameters of the pump radiation field ( 4 ) in the focus can be selected.

7 shows a schematic cross-sectional view of a fourth exemplary embodiment with 36 passages of the pump radiation field through the solid-state disk, in which only individual intermediate focus deflection optics arranged in the intermediate focus are used, likewise when drawing the reflection regions on the reflection optics, and the reflection areas on the deflecting prisms and omitting the solid-state disk, as well as the exact course of the pump radiation field.

8th FIG. 12 illustrates a schematic cross-sectional view of a fifth embodiment with 60 passes of the pump radiation field through the solid state disk, similar to the embodiment as shown in FIG 5 is shown, however, an additional Zwischenfokusumlenkelement and an areal magnified reflection optics.

LIST OF REFERENCE NUMBERS

1

Pump light arrangement

2

Solid state disk

3

excitation source

4

Pump radiation field

5

Strahlfeld guidance system

6

Incident / Dropping branch

7

reflective optics

8th

reflection area

9

reflective layer

10

deflecting

11

Zwischenfokusumlenkoptik

12

coupling optic

13

Einkopplungfokus

14

Strahlbündelumlenkoptik

15

intermediate focus

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102011004204 A [0003]

Claims (10)

Pumping light arrangement ( 1 ) comprising a solid state disk comprising a laser active medium ( 2 ), an excitation source ( 3 ) for generating a pump radiation field ( 4 ) for exciting the laser-active medium, a beam field guidance system ( 5 ) to form several different in the solid state disk ( 2 ) incident branches ( 6 ) of the pump radiation field ( 4 ) with at least one reflection optics ( 7 ) with reflection areas ( 8th ) for the incident and after penetration of the solid disk ( 2 ) on a reflection layer ( 9 ) reflected, failing branches ( 6 ) of the pump radiation field ( 4 ), as well as several deflection optics ( 10 ) for coupling at least one of the solid state disk ( 2 ) failing branch ( 6 ) to one into the solid state disk ( 2 ) incident branch ( 6 ) and a coupling-in optics ( 12 ) for guiding the pump radiation field ( 4 ) into the beam field guidance system ( 5 ), characterized in that the coupling optics ( 12 ) when coupling the pump radiation field ( 4 ) into the beam field guidance system ( 5 ) for generating a coupling focus ( 13 ) is trained. Pumping light arrangement ( 1 ) according to claim 1, characterized in that the beam field guidance system ( 5 ) at least one Zwischenfokusumlenkoptik ( 10 . 11 ) in the area of an intermediate focus ( 15 ) in one of the over the deflection optics ( 10 . 11 ) coupled to each other and falling branches ( 6 ) is arranged and the coupling optics ( 12 ) and the beam field guiding system ( 5 ) are designed so that the coupling focus ( 13 ) in the area of Zwischenfokusumlenkoptik ( 10 . 11 ) is arranged. Pumping light arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the distance between the coupling focus ( 13 ) and reflection optics ( 7 ), as well as between Zwischenfokusumlenkoptik ( 10 . 11 ) and reflection optics ( 7 ) is exactly "f". Pumping light arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the distance between at least one other deflecting optics ( 10 ) as the Zwischenfokusumlenkoptik ( 10 . 11 ), in whose area the coupling focus ( 13 ) is greater or smaller than "f". Pumping light arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the coupled pump radiation field ( 4 ) and the Zwischenfokusumlenkoptik ( 10 . 11 ), in whose area the coupling focus ( 13 ) are arranged in azimuthal (or radial) direction to each other and the beam field guiding system ( 5 ) at least one further Zwischenfokusumlenkoptik ( 10 . 11 ) that has a failing branch ( 6 ) also in an azimuthal (or radial) direction into an incident branch ( 6 ). Pumping light arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the intermediate focus ( 15 ) is smaller than the beam diameter on the solid disk ( 2 ). Pumping light arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the distance of the coupled pump radiation field ( 4 ) to the adjacent Zwischenfokusumlenkoptik ( 10 . 11 ) can be varied, for example by a pump radiation source which can be displaced in this direction ( 4 ) and / or coupling optics ( 12 ). Pumping light arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the coupled-in branch ( 6 ) and the Zwischenfokusumlenkoptik ( 11 ), in whose area the coupling focus ( 13 ) are arranged azimuthally (or radially) to each other and all other deflection optics ( 10 ), which transfer two branches in the azimuthal (or radial) direction, likewise in the region of the respective intermediate focus ( 15 ) of the deflection optics ( 10 ) are arranged together coupled branches. Pumping light arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the coupled-in branch ( 6 ) and the Zwischenfokusumlenkoptik ( 11 ), in whose range the Einkoppelfokus ( 13 ) are arranged azimuthally (or radially) to each other and the beam field guiding system ( 5 ) at least one beam deflection optics ( 14 ), which has several failing branches ( 6 ) into several incident branches ( 6 ), in each case via the Strahlbündelumlenkoptik ( 14 ) coupled to one another and falling branches ( 6 ) are arranged exclusively in the radial (or azimuthal) direction. Pumping light arrangement ( 1 ) according to claim 9, characterized in that the beam deflection optics ( 14 ) also in the area of the intermediate focus ( 15 ) via the beam deflection optics ( 14 ) coupled branches ( 6 ) and all via the beam deflection optics ( 14 ) guided from each one in and outgoing branch ( 6 ) existing branch pairs ( 6 ) are arranged exclusively in the azimuthal (or radial) direction.

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