WO2005017601A1 - Device for shaping a light beam - Google Patents

Abstract

The invention relates to a device for shaping a light beam (1), comprising first lens array means (4) with two groups of cylinder lenses (7, 8), at right angles to each other, forming the lens elements (9) through which the light beam (1) for shaping can at least partly pass. The device further comprises second lens array means (3) through which the light beam (1) for shaping can at least partly pass before incidence on the first lens array means (4), such that partial beams of the light beam (1) are incident on the individual lens elements (9) of the first lens array means (4) which do not have a quadratic cross-section.

Description

 Device for shaping a light beam

The present invention relates to a device for shaping a light beam, comprising first lens array means with two groups of mutually perpendicular cylindrical lenses, which form lens elements through which the light beam to be shaped can at least partially pass.

A device of the aforementioned type is from the international

Patent application WO 98/10314 known. Various forms of beam shaping devices are described in this patent application. One of these embodiments comprises a transparent substrate which has convexly curved entry and exit surfaces, a large number of cylindrical lenses being formed in each case on these convexly curved entry and exit surfaces. The cylindrical lenses are arranged parallel to one another on each of the surfaces, the cylindrical lenses of the entry surface being arranged perpendicular to the cylindrical lenses of the exit surface. Such devices for beam shaping can in particular also be used as a homogenizer because, in particular, beams with an inhomogeneous beam cross section can be divided up in so many different ways by the lens elements formed by the large number of cylindrical lenses that a comparatively homogeneous beam can be achieved after corresponding overlaying of the individual partial beams. In the above-described embodiment of a device for beam shaping, the cylindrical lenses form lens elements with an essentially square cross section in a direction perpendicular to the direction of propagation of the light beam to be shaped on the entry and exit surfaces. Subsequent superimposition of the partial beams that have passed through the individual square lens elements results in a focus area of the shaped light beam, which likewise has a square cross section. A light beam with such a square cross section can be coupled into a circular aperture, for example, with great difficulty. Furthermore, there are various applications in which beams with a circular cross section are desirable.

The aforementioned international patent application further discloses a device for beam shaping which has a transparent substrate with cylindrical lenses on the entry and exit surfaces, the cross section of the lens elements being essentially hexagonal on both the entry and the exit side. If partial beams that have passed through such lens elements are superimposed, this results in a shaped light beam with an essentially hexagonal cross section. Such a hexagonal cross-section can be coupled into a circular aperture with less losses than a beam with a square cross-section. A disadvantage of this embodiment of the device for beam shaping known from the aforementioned international patent application is that the hexagonal cylindrical lens elements on the entry and exit sides can only be produced with great effort in terms of production technology.

The problem on which the present invention is based is the creation of a device of the type mentioned at the outset, which is comparatively simple to manufacture and which has a cross section of the shaped one which is approximated to a circular cross section

Has light beam. This is achieved according to the invention by a device of the type mentioned at the outset with the characterizing features of claim 1. The subclaims relate to preferred developments of the invention.

According to claim 1, it is provided that the device further comprises second lens array means through which the light beam to be formed can at least partially pass before striking the first lens array means in such a way that partial rays of the light beam that do not square are incident on the individual lens elements of the first lens array means Have cross-section. The shaping of the cross-section of the partial beams deviating from a square cross-section is therefore not carried out by the first lens array means but by additional second lens array means. This way the first

Lens array means to be comparatively simple, in particular as a commercially available lens array with crossed cylindrical lenses on the entrance and exit surfaces. Such a lens array can be produced very inexpensively.

The development according to claim 2 provides that the cross section of the partial beams of the light beam impinging on the first lens array means is essentially octagonal, in particular corresponds to a regular octagon. A light beam with an octagonal cross section can be used with significantly smaller ones

Introduce losses into a circular aperture as a beam of light with a square or a hexagonal cross section.

The development according to claim 3 provides that the two groups of mutually perpendicular cylindrical lenses of the first lens array means are designed such that the cross section of the lens elements is essentially square. This Square lens elements automatically result in the aforementioned commercially available lens arrays with cylindrical lenses on the entry and exit surfaces, which are crossed to one another if the cylindrical lenses each have the same dimension in the transverse direction.

The development according to claim 4 provides that the second lens array means comprise a plurality of elongated lens arrays.

According to claim 5, it can be provided that the plurality of elongated lens arrays are aligned with respect to their longitudinal extension at an angle of 45 ° to the cylinder axes of the two groups of mutually perpendicular cylindrical lenses of the first lens array means.

The development according to claim 6 provides that the elongated lens arrays are arranged parallel and spaced apart from one another in such a way that partial beams of the light beam to be shaped can pass through the lens arrays and other partial beams of the light beam to be shaped can pass between the lens arrays.

The development according to claim 7 provides that at least some of the elongated lens arrays have lens elements arranged next to one another in their longitudinal direction.

According to the development specified in claim 8, these lens elements can be designed as cylindrical lenses or cylinder-like lenses, the cylinder axes of which are perpendicular to

Longitudinal extension of the lens arrays and in particular also vertically are aligned with the direction of propagation of the light beam to be shaped.

In a preferred embodiment of the present invention according to claim 9, the lens elements of the lens arrays are designed such that a partial beam which has passed through one of the lens arrays has a smaller extent after passing through in the longitudinal direction of the lens arrays than before passing through. Such a partial beam can thus propagate behind the lens array of the second

Lens array means strike the first lens array means, with no partial beams striking individual regions of the lens elements of the first lens array means. These areas are aligned with the second lens array means in the direction of propagation of the light beam. In particular, there is the possibility that the second lens array means cover corner areas of the lens elements of the first lens array means at the aforementioned angle of 45 ° in such a way that no partial beams strike exactly this corner area. In this way, the aforementioned octagonal cross section of the partial beams incident on the lens elements can be achieved.

The development according to claim 10 provides that each of the lens elements of the lens array has a convex cylindrical lens on its side facing away from the first lens array means and a concave cylindrical lens on its side facing the first lens array means. Such a configuration of the lens elements enables the aforementioned narrowing of the partial beam passing through each of the lens elements to be achieved with simple means. The preferred further development according to claim 11 provides that the device further comprises third lens array means through which the light beam to be shaped can at least partially pass before striking the second lens array means.

According to claim 12, the third lens array means can be designed such that the light beam to be shaped after passing through the third lens array means has areas of greater energy density and areas of lower energy density.

The development according to claim 13 provides that the areas of greater energy density essentially correspond to the partial beams that pass between the individual lens arrays of the second lens array means, whereas the areas of lower energy density essentially correspond to the partial beams that are in the

Essentially pass through the individual lens arrays of the second lens array means. This configuration of the third lens array means enables partial beams of greater energy density to pass in the regions between the individual lens arrays of the second lens array means than through the individual lens arrays of the second lens array means. Due to the fact that the partial beams passing through the individual lens arrays of the second lens array means are compressed in the longitudinal direction of the lens arrays, these partial beams have a greater energy density after the passage than before the passage.

In this way it can be ensured that after passing through the second lens array means all partial beams have essentially the same energy density, so that the octagonal cross section, for example, of the incident on the lens elements of the first lens array means

Partial rays essentially has a constant energy density, that is to say that the partial rays impinging on the lens elements are comparatively homogeneous. This leads to the fact that after superposition of all the partial beams passing through the first lens array means, the resulting shaped light beam is very homogeneous over its cross section.

According to claim 14, it can be provided that the third lens array means have a plurality of cylindrical lenses on two opposing optically functional interfaces, which correspond in particular to the entrance surface and the exit surface of the light beam to be shaped.

According to claim 15 it can be provided that the cylinder axes of the cylindrical lenses of the third lens array means are arranged parallel to one another and in particular parallel to the longitudinal extent of the elongated lens arrays of the second lens array means.

The preferred embodiment according to claim 16 provides that convex cylindrical lenses and concave cylindrical lenses are arranged alternately next to one another on each of the two opposing optically functional interfaces. With such an arrangement, the aforementioned areas of greater and smaller energy density can be achieved with simple means.

The alternative embodiment according to claim 17 provides that the cylindrical lenses arranged on the two opposite optically functional interfaces of the third lens array means are convex. With this embodiment too, the generation of partial beams of differently large energy densities can be realized with comparatively simple means. Further features and advantages of the present invention will become clear from the following description of preferred exemplary embodiments with reference to the accompanying figures. Show in it

Figure 1 is a schematic plan view of a device according to the invention.

2a shows a detailed top view of first lens array means of the device according to the invention;

FIG. 2b shows a side view of the first lens array means according to FIG. 2a;

3a shows a schematic front view of second lens array means with the first lens array means of the device according to the invention located behind them;

3b shows a detailed view according to arrow II I b in FIG. 3a;

4a shows a detailed side view of first, second and third lens array means of the device according to the invention;

4b shows a side view of the lens array means according to FIG. 4a rotated by 90 °;

5 shows a detailed side view of a further embodiment of third lens array means with the second lens array means according to FIGS. 4a and 4b.

Cartesian coordinate systems are shown in the figures for clarity. In particular in Fig. 3a and Fig. 3b, two different Cartesian coordinate systems are shown, which are rotated relative to one another by an angle of 45 °.

From Fig. 1 it can be seen that an inventive device for

Forming a light beam 1 essentially three lens array means

2, 3, 4 comprises, through which the light beam can pass. Subsequently, a Fourier lens 5 is drawn in in FIG. 1, which can superimpose the light that has passed through the lens array means 2, 3, 4 in a Fourier plane 6.

2a and 2b show the first lens array means 4 through which the light beam 1 passes in the positive Z direction as the last of the three lens array means 2, 3, 4. The name of the first lens array means 4 appears in the order of the lens array means 2,

3, 4 to contradict in the beam direction, but is quite useful due to the explanation of the functions of the individual lens array means 2, 3, 4 set out below. The first lens array means 4 essentially consist of an array of cylindrical lenses 7 on a first optically functional interface, which serves as an entry surface, and a second array of cylindrical lenses 8 on a second optically functional interface, which serves as an exit surface. The cylinder axes of the cylindrical lenses 7, 8 are aligned perpendicular to each other, so that these crossed cylindrical lenses 7, 8 form lens elements 9, which in the

Essentially have a square cross section (see Fig. 3a). The cylindrical lenses 7, 8 can have both a spherical and an aspherical shape of their outer surface. Furthermore, there is also the possibility of taking 8, 8 cylinder-like lenses instead of cylindrical lenses, which may have their

The longitudinal extent does not have a constant radius. 3a, 3b, 4a and 4b show second lens array means 3, which are arranged in the positive Z direction of the light beam 1 in front of the first lens array means 4, so that the light that has passed through the second lens array means 3 enters the first lens array means 4.

3a and 3b show that the second lens array means 3 consist of a plurality of narrow, elongated lens arrays 11, which are arranged at an angle of 45 ° to the axes of the cylindrical lenses 7, 8. This can be seen from FIG. 3a by the fact that the cylindrical lenses 7, 8 which are crossed relative to one another form a checkerboard-like pattern with lens elements 9. Furthermore, the two Cartesian coordinate systems X, Y and X ', Y' rotated by an angle of 45 ° to one another indicate the rotation of the lens array 11 relative to the axes of the cylindrical lenses 7, 8. In particular, FIGS. 2a and 2b show that the cylinder axes of the cylinder lenses 7 extend in the X direction and that the cylinder axes of the cylinder lenses 8 extend in the Y direction. In contrast, the long, narrow lens arrays 11 extend in the X ′ direction (see FIG. 3a), which is rotated by 45 ° with respect to the X direction and the Y direction.

The elongated lens arrays 11 comprise lens elements 12 arranged next to one another in the X ′ direction, each of which extends diagonally over approximately one of the square lens elements 9

(See Fig. 3b). The lens elements 12 thus end approximately at the crossing points of the lens elements 9.

4b shows that the individual lens elements 12 of the lens arrays 11 in the Z direction or Z 'direction on their front or

Back side cylindrical lenses 16, 17 have. Each of the cylindrical lenses 16, 17 can have a spherical or a square lateral surface have a cylinder axis in the Y 'direction. The cylindrical lenses 16 arranged on the front side, that is to say on the left in FIG. 4b, are convex in shape, whereas the cylindrical lenses arranged on the rear side and thus on the side facing the first lens array means 4 have a concave shape. That in the positive Z direction or

The Z 'direction from the left in FIG. 4b light incident on the cylindrical lenses 16 is refracted inwards by the latter in such a way that the light emerging from the cylindrical lenses 17 shown on the right in FIG. 4b runs essentially parallel to the incident light. FIG. 4b shows, however, that the extent of the partial beam that has passed through a single lens element 12 in the X ′ direction is smaller after it has passed than before it has passed through the lens element 12. 4 regions 13 thus arise on the first lens array means where there is no light. The light of these areas 13 is in the neighboring in the X 'direction

Areas 14 deflected (see Fig. 3b and Fig. 4b).

Due to the fact that no light strikes the regions 13 shown in FIG. 3b, the partial beams incident on the individual lens elements 9 of the first lens array means 4 have an im

Essentially octagonal cross-section 10, which is clearly visible from Fig. 3b.

4a and 4b also show a first embodiment of the third lens array means 2, which are arranged in the direction of propagation Z and Z 'of the light beam 1 in front of the second lens array means 3. The light that has passed through the third lens array means 2 thus partially passes through the second lens array means 3 before it strikes the first lens array means 4. The embodiment of the third lens array means 2 depicted in FIGS. 4a and 4b comprises convex and concave cylindrical lenses 18a, 18b on the front and left side in FIGS. 4a and 4b as well as convex and concave cylindrical lenses 19a, 19b on the back. Both on the front and on the back, convex cylindrical lenses 18a, 19a alternate with concave cylindrical lenses 18b, 19b. In this case, convex cylindrical lenses 18a on the front side and concave cylindrical lenses 19b on the rear side are always opposite one another, and concave cylindrical lenses 18b on the front side are convex cylindrical lenses 19a on the rear side. The

Cylinder axes of the convex and concave cylindrical lenses 18a, 19a, 18b, 19b extend essentially in the X 'direction.

4a can also be seen that the convex cylindrical lenses

18a have a greater extent in the Y ′ direction than the concave cylindrical lenses 19b on the rear side. 4a that the concave cylindrical lenses 18b on the front in the Y ′ direction have a smaller extent than the convex cylindrical lenses 19a on the rear of the third

Lens array means 2. This configuration of the front and rear sides of the third lens array means 2 ensures that a light beam 1 which is essentially homogeneous in the Y ′ direction has areas of greater and lesser density after passing through the third lens array means 2 in the Y ′ direction , 4a are the

Provide areas of greater density with the reference number 15. The partial beams of greater density, as is clearly evident from FIG. 4a, each pass between the individual elongated lens arrays 11. The partial beams of lower density strike the individual lens arrays 11 and pass through them. The third lens array means 2 can thus achieve that more light passes through the areas 15 between the individual lens arrays 11 of the second lens array means 3 than through the respective lens arrays 11. This is clearly illustrated again in FIG. 3 b, in which the regions 15 of greater density in the octagonal cross section 10 of the partial beam impinging on a single lens element 9 are arranged in the Y ′ direction adjacent to the region 14, in which through the lens elements 12 of the second lens array means 3, more light is introduced. According to the invention, the second and third lens array means 3, 2 can be designed in such a way that the partial beams with an octagonal cross section 10 impinging on each of the lens elements 9 each have approximately the same energy density both in the regions 15 and in the regions 14.

The partial beams with an octagonal cross section 10 and a substantially uniform intensity distribution are superimposed on one another in the Fourier plane 6 in such a way that a focus area with an essentially octagonal cross section is created. This octagonal cross section is much closer to the circular shape than a square one

Cross-section, so that such a focus area with an octagonal cross-section can be introduced more effectively and with lower losses into circular apertures.

5 is a second embodiment of the third

Lens array means 20 can be seen. 5, the same parts are provided with the same reference numerals. The third lens array means 20 have convex cylindrical lenses 21 a, 21 b, 22a, 22b both on their front side and on their rear side. On the front are alternately wider cylindrical lenses 21a in the Y'-direction and in the Y'-

Direction narrower cylindrical lenses 21 b arranged side by side. Likewise, wider ones are alternately in the Y 'direction on the back Cylinder lenses 22a and cylinder lenses 22b which are narrower in the Y ′ direction are arranged next to one another. The cylinder axes of the cylindrical lenses 21 a, 21 b, 22a, 22b extend essentially in the X ′ direction. From Fig. 5 it can also be seen that in each case the wider cylindrical lenses 21 a on the front of the narrower cylindrical lenses

22b on the back and the narrower cylindrical lenses 21b on the front face the wider cylindrical lenses 22a on the back. This arrangement ensures that a light beam 1, which was previously essentially homogeneous in the Y 'direction, after passing through the lens array means 20 in Y'-

Direction alternately side by side areas of greater and lesser density, as already shown by the in Fig. 4a and 4b shown third lens array means 2 was achieved.

In the alternative embodiment of the third lens array means 20 shown in FIG. 5, the lateral surfaces of the cylindrical lenses can be designed aspherically.

A device according to the invention can be produced, for example, by cutting the second lens array means 3 out of a flat two-dimensional array. Subsequently, the individual elongated lens arrays 11 of the second lens array means 3 can be introduced spaced apart from one another in a position frame which allows exact positioning with respect to the first lens array means 4. Then the second lens array means 3 can be connected, for example glued, to the first lens array means 2.

Claims

claims:

1 . Device for shaping a light beam (1), comprising first lens array means (4) with two groups of mutually perpendicular cylindrical lenses (7, 8), which form lens elements (9) through which the light beam (1) to be shaped can at least partially pass, characterized in that the device further comprises second lens array means (3) through which the light beam (1) to be shaped can pass at least partially before striking the first lens array means (4) in such a way that the individual lens elements (9) of the first lens array means (4) partial beams of the light beam (1) strike which have a non-square cross section.

2. Device according to claim 1, characterized in that the cross section of the partial beams of the light beam (1) impinging on the first lens array means (4) is essentially octagonal, in particular corresponds to a regular octagon.

3. Device according to one of claims 1 or 2, characterized in that the two groups of mutually perpendicular cylindrical lenses (7, 8) of the first lens array means (4) are designed such that the cross section of the lens elements (9) is substantially square ,

4. Device according to one of claims 1 to 3, characterized in that the second lens array means (3) comprise a plurality of elongated lens arrays (1 1).

5. The device according to claim 4, characterized in that the plurality of elongated lens arrays (1 1) with respect to their longitudinal extent at an angle of 45 ° to the cylinder axes of the two groups of mutually perpendicular cylindrical lenses (7, 8) of the first lens array means (4th ) are aligned.

6. Device according to one of claims 4 or 5, characterized in that the elongated lens arrays (1 1) are arranged parallel and spaced from one another in such a way that partial beams of the light beam to be formed (1) can pass through the lens arrays (1 1) and others Partial beams of the light beam to be formed (1) can pass between the lens arrays (1 1).

7. Device according to one of claims 4 to 6, characterized in that at least some of the elongated lens arrays (1 1) in their longitudinal direction arranged side by side lens elements (12).

8. The device according to claim 7, characterized in that the lens elements (12) of the lens arrays (1 1) are designed as cylindrical lenses (16, 17) or cylinder-like lenses, the cylinder axis perpendicular to the longitudinal extension of the lens arrays (1 1) and in particular also are aligned perpendicular to the direction of propagation (Z, Z ^' ) of the light beam to be shaped.

9. Device according to one of claims 7 or 8, characterized in that the lens elements (12) of the lens arrays (1 1) are designed such that a partial beam passing through one of the lens arrays (12) after passing through in the longitudinal direction of the lens array (1 1) has a smaller extent than before the passage.

10. The device according to claim 9, characterized in that each of the lens elements (12) of the lens array (1 1) on its side facing away from the first lens array means (4) a convex cylindrical lens (16) and on its the first lens array means (4) facing side has a concave cylindrical lens (17).

1 1. Device according to one of claims 1 to 10, characterized in that the device further comprises third lens array means (2, 20) through which the light beam to be formed (1) can at least partially pass before striking the second lens array means (3).

12. The device according to claim 1 1, characterized in that the third lens array means (2, 20) are designed such that the light beam to be formed (1) after passing through the third lens array means (2, 20) areas (15) of greater intensity and Has areas (13, 14) of lower intensity.

13. The apparatus according to claim 12, characterized in that the areas (15) of greater energy density substantially correspond to the partial beams that pass between the individual lens arrays (1 1) of the second lens array means (3), whereas the areas (13, 14) less Energy density essentially corresponds to the partial beams which essentially pass through the individual lens arrays (11) of the second lens array means (3).

14. Device according to one of claims 1 1 to 13, characterized in that the third lens array means (2, 20) Two opposing optically functional interfaces, which correspond in particular to the entrance surface and the exit surface of the light beam (1) to be shaped, have a plurality of cylindrical lenses (18a, 18b, 19a, 19b, 21a, 21b, 22a, 22b).

15. The apparatus according to claim 14, characterized in that the cylinder axes of the cylindrical lenses (18a, 18b, 19a, 19b, 21 a, 21 b, 22a, 22b) of the third lens array means (2, 20) parallel to one another and in particular parallel to the longitudinal extension of the elongated lens arrays (1 1) of the second lens array means (3) are arranged.

16. Device according to one of claims 14 or 15, characterized in that convex cylindrical lenses (18a, 19a) and concave cylindrical lenses (18b, 19b) are arranged alternately next to one another on each of the two opposing optically functional interfaces.

17. Device according to one of claims 1 1 to 15, characterized in that the cylindrical lenses (21 a, 21 b, 22a, 22b) arranged on the two opposing optically functional interfaces of the third lens array means (20) are convex.

18. lens array means for generating partial beams of different energy density, characterized by the features of the third lens array means (2) relating to one or more of claims 1 to 16.

19. Lens array means for generating partial beams of different energy density, characterized by the Features relating to lens array means (20) of one or more of claims 1 1 to 15 and 17.