EP1743204A1

EP1743204A1 - Device and method for optical beam homogenization

Info

Publication number: EP1743204A1
Application number: EP05716566A
Authority: EP
Inventors: Vitalij Lissotschenko; Aleksei Mikhailov; Maxim Darsht; Iouri Mikliaev
Original assignee: Hentze Lissotschenko Patentverwaltungs GmbH and Co KG
Current assignee: Limo GmbH
Priority date: 2004-04-26
Filing date: 2005-04-09
Publication date: 2007-01-17
Also published as: KR101282582B1; JP4875609B2; WO2005103795A1; CN1947053A; DE102004020250A1; US20070127131A1; KR20070018918A; JP2007534991A; CN100465698C

Abstract

The invention relates to a device for optical beam homogenization, which comprises at least one optically functional boundary surface for passage of a beam to be homogenized or for reflection of a beam to be homogenized, and a plurality of lens elements (4, 5) or mirror elements that are disposed on the at least one optically functional boundary surface. The lens elements (4, 5) or the mirror elements are curved in their marginal areas to such an extent as to reduce diffraction-related effects.

Description

"Device and method for optical beam homogenization"

The present invention relates to a device for optical beam homogenization, comprising at least one optically functional interface through which a beam to be homogenized can pass or on which a beam to be homogenized can be reflected, and to a multiplicity of lens elements or mirror elements which are optically arranged on the at least one functional interface are arranged. Furthermore, the present invention relates to a method for producing a device for optical beam homogenization with at least one optically functional interface through which a beam to be homogenized can pass or on which a beam to be homogenized can be reflected, as well as a large number of lens elements or mirror elements the at least one optically functional interface are arranged.

A device and a method of the type mentioned at the outset are known from US Pat. No. 6,239,913 B1. The device described therein has a transparent substrate, in which arrays of cylindrical lenses are arranged both on a light entry surface and on a light exit surface. The arrays of cylindrical lenses have mutually perpendicular cylindrical axes. The individual cylindrical lenses can have a spherical or else an aspherical cross-section of the second order. For beam homogenization, for example, collimated laser radiation is guided through the device and, following the device, brought together into a working plane by means of a converging lens serving as a Fourier lens. The light refracted by the individual cylindrical lens elements becomes superimposed in the working plane by means of the Fourier lens in such a way that the original laser radiation is homogenized.

A disadvantage of a device of the aforementioned type proves that, due to diffraction effects, the light distribution of the light that has passed through individual lens elements has noticeable intensity fluctuations (see FIG. 2). The intensity fluctuations in the light distribution of an individual lens element are not extinguished even when the light of all the lens elements is superimposed because the light that has passed through the individual lens elements is superimposed in a similar manner in the working plane for each lens element.

The problem on which the present invention is based is the creation of a device of the type mentioned at the outset, which can generate homogenized light with fewer fluctuations in intensity. Furthermore, a method of the type mentioned at the outset for producing a device for optical beam homogenization is to be specified, in which the homogenized light has fewer intensity fluctuations.

This is achieved according to the invention with regard to the device by a device of the type mentioned at the outset with the characterizing features of claim 1 or the characterizing features of claim 5 and in terms of the method by a method of the type mentioned at the beginning with the characterizing features of claim 8. The subclaims relate to preferred developments of the invention.

According to claim 1, it is provided that the lens elements or the mirror elements each have one in their edge regions Have curvature that diffraction-related effects are reduced. The effects to be avoided are predominantly effects which are similar to edge diffraction effects, whereby such edge diffraction effects can be changed, in particular smeared, by the change in the edge region according to the invention, in particular such that the intensity fluctuation of the light distribution which has passed through a single lens element or that of an individual mirror element reflected light distribution can be greatly reduced.

Devices according to the invention are suitable for a wide spectral range from the far infrared to the X-ray range. In the VUV, XUV and X-ray area in particular, the use of mirror elements instead of lens elements has proven to be extremely useful.

It is also possible to provide more than one optically functional interface, for example two or four. The lens or mirror elements of all or only individual optically functional interfaces can then be changed such that a better homogenization of the light is achieved.

According to claim 2, it can be provided that the lens elements or the mirror elements have a cross-section in a central region which essentially corresponds to an aspherical cross-section of the second order, such as a hyperbolic or a parabolic cross-section. According to claim 3, it can be provided that the lens elements or the mirror elements have a cross section in their edge regions that is of an aspherical cross section second order deviates, in particular deviates very strongly. This deviation can be designed in such a way that the lens elements or the mirror elements have a cross section in their edge regions which is dominated by higher orders of a polynomial, in particular by higher straight orders of a polynomial. Under certain circumstances, the edge areas can only be mathematically described separately from the middle area by a polynomial. By dominating the cross-section in the edge regions of the lens elements or the mirror elements by higher orders of a polynomial, the aforementioned edge diffraction effects can be influenced in a targeted manner, so that the one emerging from the homogenizer or from the individual lens elements of the homogenizer or from the individual mirror elements is comparatively effective reflected light distribution can be smoothed.

According to claim 5 it is provided that each of the lens elements or the mirror elements is provided with a wavy or sinusoidal structure. In particular, the periodicity of the structure can be smaller, in particular smaller than the periodicity with which the individual lens elements or mirror elements are arranged next to one another. For example, each of the lens elements or the mirror elements can have a basic structure on which the wave-shaped or sinusoidal structure is based, which is spherical or aspherical of the second order. The wave-shaped or sinusoidal structure on each of the lens elements or mirror elements enables the intensity of the light distribution of the homogenizer to be averaged, so that the overall light distribution can be made more uniform. The method according to claim 8 is characterized by the following method steps: a device for optical beam homogenization with at least one optically functional interface and a plurality of lens elements or mirror elements on the optically functional interface is produced; the light distribution of light passing through a single one of the plurality of lens elements or light reflected by a single one of the plurality of mirror elements is determined; a structure that is complementary to the determined light distribution is applied to each of the lens elements or the mirror elements.

In particular, it can be provided according to claim 9 that the structure applied has a greater amplitude in the edge regions of the lens elements or the mirror elements than in the central region of the lens elements or the mirror elements. The lens elements or mirror elements produced in the first method step can have a regular cross-section, in particular a spherical or aspherical cross-section of the second order. The lens elements or mirror elements produced in the first method step can thus be produced using simple means. The complementary structure applied to the lenses or mirrors after determination of the light distribution can be adapted with the corresponding manufacturing outlay exactly to the diffraction-related disturbance of the light distribution to be expected such that the light passing through a device for homogenization with such a structure has a very uniform light distribution after passing through or has a very uniform light distribution after reflection on the device when using corresponding mirror elements.

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

1 a shows a schematic side view of a device according to the invention;

1 b a compared to FIG. 1 a side view of the device which has been rotated by 90 °;

2 schematically shows the light distribution of light that has passed through a lens element according to the prior art;

3 schematically shows the light distribution of light which has passed through a lens element of the device according to the invention;

4 shows the cross section of a single convex lens element of a device according to the invention in comparison to a single lens element according to the prior art;

FIG. 5 shows a detailed view of the edge region of the cross section of the lens element of the device according to the invention according to FIG. 4;

6 shows the cross section of a further embodiment of a concave lens element of a device according to the invention; Fig. 7 is a detailed view of the cross section according to FIG. 1 showing the edge of the lens element. 6;

8 schematically shows the light distribution of light that has passed through the lens element according to FIG. 6.

The invention is described below using the example of lens elements through which light to be homogenized passes. The mirror elements that can also be used according to the invention for homogenization can be designed similarly or exactly like the lens elements, with the difference that they are at least partially reflective for the wavelength of the light to be homogenized. For this purpose, for example, the lens elements described below could be provided with a corresponding reflective coating. The light to be homogenized can then be reflected, for example, at the individual mirror elements at an angle other than zero.

In some of the figures, Cartesian coordinate systems are shown for better clarification of the device according to the invention.

Fig. 1 a and 1 b schematically show an exemplary embodiment of a device according to the invention for optical beam homogenization. In particular, FIGS. 1 a and 1 b show a substrate 1 made of a transparent material with an entry surface 2 and an exit surface 3 for light. A large number of lens elements 4 arranged parallel to one another are provided on the entrance surface 2 and are designed as cylindrical lenses. The cylinder axes of these cylindrical lenses extend in the Y direction. A plurality of lens elements 5 are also arranged on the exit surface 3 are also designed as parallel and spaced-apart cylindrical lenses. The cylinder axes of the lens element 5 extend in the X direction and are thus aligned perpendicular to the cylinder axes of the lens elements 4.

Due to the crossed lens elements 4, 5 designed as cylindrical lenses, when light passes through the entrance surface 2 and the exit surface 3, the light rays that have passed are refracted both in the X direction and in the Y direction, so that the lens elements 4, 5 are in their Interaction has a similar effect as a large number of spherical lens elements. According to the invention, there is certainly the possibility of providing a two-dimensional array of spherical lens elements instead of crossed cylindrical lenses. Such an array can be arranged both on the entry surface 2 and the exit surface 3 and only on the entry surface 2 or only on the exit surface 3. Furthermore, it is possible to arrange an array of cylindrical lenses only on the entry surface 2 or only on the exit surface 3, so that the light is refracted only with respect to one of the directions X, Y. Furthermore, the lens or mirror elements arranged next to one another can alternately be concave and convex on one or each of the optically functional interfaces in order to avoid losses in the transition region between individual lens or mirror elements.

The embodiment of a device according to the invention depicted in FIG. 1 a and in FIG. 1 b can be used for homogenizing a laser beam, wherein, for example, parallel light is directed onto the device and a collecting lens serving as a Fourier lens can be provided behind the device in the beam direction, that overlap through many, or all of the lens elements 4, 5 led light in the focal plane of the Fourier lens. Such structures are well known from the prior art. Alternatively, a slightly different inclination of the individual lens elements 4, 5 can also lead to an overlay in the far field. A separate Fourier lens can then be dispensed with here.

In Fig. 1 a and Fig. 1 b, the individual lens elements 4, 5 are indicated schematically by a semicircle. The shape of the individual lens elements is only roughly simplified. 4 shows in detail the shape of an embodiment of a lens element of a device according to the invention. In particular, in FIG. 4 the upper graphic shows the cross section 6 of a cylindrical lens known from the prior art with an essentially aspherical cross section of the second order. The lower graphic shows in Fig. 4 shows the cross section 7 of a lens element of a first embodiment of a device according to the invention. 4 shows that the cross section 7, in particular in the edge region of the lens element, deviates from the aspherical cross section 6 of the second order according to the prior art. In FIG. 4, the expansion of the lens element in the Z direction is plotted (see FIGS. 1 a and 1 b). The abscissa of the graphic according to FIG. 4 shows the X coordinate of the lens element in millimeters, the 0 being arranged in the center of the cross section of the lens element. The graph according to FIG. 4 shows that the deviation of the cross section 7 of the lens element of the device according to the invention from the parabolic cross section 6 according to the prior art becomes noticeable for X values beziehungsweise -0.4 mm or> 0.4 mm.

5, in particular, it can be seen that in the edge region of the lens element the cross section is significantly more curved than in FIG adjoining area. In particular, a very significant increase in the curvature of the cross section can be seen at X values <-0.647 mm or at X values> 0.647.

2 shows the light distribution in intensity versus exit angle for a lens element with an aspherical cross-section 6 of the second order according to the prior art. In particular, one sees here disturbing diffraction-related intensity fluctuations for different light exit angles. 3 shows on the same scale the light distribution of a lens element 4, 5 with a cross section 7 according to FIG. 4 of a device according to the invention. It can be clearly seen that the diffraction-related fluctuations in intensity are significantly lower here, which is due to the deviation of the cross-section from the second-order asphere in the edge region of the lens element 4, 5.

From Fig. 6 and Fig. 7 shows a second embodiment of a lens element 4, 5 of a device according to the invention. FIG. 7 in particular shows that this embodiment also has a sharp increase in curvature in its edge region. 8 shows the light distribution of light that has passed through such a lens element 4, 5 in intensity as a function of the exit angle. The light distribution shows hardly noticeable fluctuations in intensity for different exit angles, which can also be attributed here to the special shape of the lens element 4, 5 in its edge region.

The example for the cross section of a lens element 4, 5 shown in FIGS. 6 and 7 is described in detail below. In particular, the cross section can be represented mathematically in sections as a twelfth degree polynomial, according to the following formula: z (x) = u ₅ I xI ⁵ + U _Λ • I x I ⁶ + 10 U ₇ ■ x + U _s ^■ x + U ₉ ■ x + U _w ■ x + I \ I ¹¹ TT | 12 x \ + U, 1

with the following coefficients:

In a first x-value range with 0 <| x | <0.560

U ₀ = -1.66-10 -2

U _λ = 0

C /, = -3.34-10 ^" t / ₃ = 0

U ₄ = -2.48-10 ^"

U _< = 0 t / ₆ = -l ₅ 00-10 ^_

U _η = 0 t ₈ = -5.57-10 -7

t / ₉ = 0

C /, ₀ = 1.81-10- u _n = o

L7 ₁₂ = -2.18-10 ^"

In a second x value range with 0.560 <| x | <0.650

£ .- = - 6,15-10-

CJ _! = 3,74-10-

C / ₂ = -3,34-10- t / ₃ = 7,67-10- ⁴ £ ₄ = -2,96-10 ^" U _s = 6.42-10 ^" U ₆ = -1.70-10 '£ ₇ = 3.55-10 ² U _a = -7.34-10 °

U ₉ = - -2.58 -10 ⁴

H ₁₀ = l, ⁵ t 21-10 _π = 5.83 to 10 ⁵ £ ₁₂ = -2,66-10 ⁶

In a third x-values range with 0.650 <| x | <0.688 t / ₀ = -2,51-10- ³ t / _x = 4.39 to 10 ^"2

£ / ₂ = 4.95-10 ^{~ 2} c7 ₃ = 2.16-10 ^_1

£ / ₄ = 4.29-10 't / ₅ = -6.24-10 ³

H ₆ = 6.70-10 ⁵

H ₇ = -4.6M0 ⁷ t ₈ = 2, ll-10 ⁹ t ₉ = -6.38-10 ¹⁰

H ₁₀ = 1.23-10 ¹²

U _U = -1.36Λ ^U

£ / ₁₂ = 6.70-10 ¹³

In a fourth x-value range with 0.688 <| x | <0.698 t / ₀ = -7.20-10- ⁴ C / _j = 5.41-10 ^{~ 2} U ₂ = 6.32-10- 't ₃ = -2.49-10 ² t / ₄ = 2.84-10 ⁵ t / ₅ = -l, 71- 10 ⁸

H - = - l, 69-10 ¹³ tL = 2.88-10 ¹⁵ t / ₁₀ = 2.35-10 ¹⁹ t / _π = -9.72-10 ²⁰ ZN ₁₂ = 1.78-10 ²²

It turns out that in the middle area of the lens element, over a very extensive area up to about 0.56 mm from the center, the shape of the cross section is essentially determined by the coefficient U ₂ , which is assigned to the square term of X. In other words, an essentially aspherical configuration of the second order of the cross section of the lens element results in this central region. Compared to the comparatively large coefficient U ₂ , the other coefficients U _4l U ₆ , Us, U-io, U- | ₂ negligible small. It also shows that all the odd coefficients Ui, U ₃ , U ₅ , U ₇ , Ug, Un are equal to 0.

In the second X value range between 0.56 and 0.65, the shape of the cross section of the lens element is no longer determined primarily by the coefficient U ₂ , because, for example, the coefficient U1 assigned to the linear term of X has a magnitude comparable to that of U ₂ . Furthermore, higher orders coefficients assigned by X are significantly larger, so that they are sometimes also significant; here, reference should be made to the coefficient Uι ₂ by way of example.

This increase in the coefficients assigned to the higher orders of X continues in the third range of values and in particular in the fourth range of values, where the coefficient Uι ₂ is more than 20 orders of magnitude larger than the coefficient U ₂ .

In a further embodiment, not shown, of a device according to the invention, essentially regularly structured lenses with, for example, second-order Ashary cross-section can be used. However, a fine, in particular wavy or sinusoidal structure is impressed on all the lens elements here. The periodicity of this structure is smaller, in particular small compared to the periodicity with which the individual lens elements 4, 5 are arranged side by side on the entrance surface 2 or the exit surface 3. With such a fine structure applied to the lens elements 4, 5, the light distribution emerging from the individual lens elements or from the entire device is averaged, so that the light distribution shown in FIG. 2 disturbances shown can also be reduced.

In a further embodiment of the present invention, also not shown, a structure is applied to the individual lens elements 4, 5 that is complementary to a disturbance, as is shown, for example, in FIG. 2. According to a method according to the invention, this is achieved in that in a first step a substrate is provided with lens elements which have a regular cross section, such as a spherical or an aspherical cross section of the second order exhibit. Subsequently, the light distribution of light passing through such a lens element is determined. Such a light distribution could, for example, correspond to the light distribution according to FIG. 2. Subsequently, either the already existing lens elements are changed in such a way that they have a structure that is complementary to the disturbance shown, for example, in FIG. 2, or else new lens elements are generated in a new substrate or in the same substrate, ie they have a cross section, the one with, for example, Fig. 2 complementary structure is provided.

In particular, a structure is thus applied to a lens element with a spherical or aspherical cross-section of the second order which varies in the edge region of the lens element with a greater amplitude than in the central region of the lens.

Claims

claims:

1 . Device for optical beam homogenization, comprising at least one optically functional interface through which a beam to be homogenized can pass or on which a beam to be homogenized can be reflected; a plurality of lens elements (4, 5) or mirror elements which are arranged on the at least one optically functional interface; characterized in that the lens elements (4, 5) or the mirror elements each have such a curvature in their edge regions that they reduce effects caused by diffraction.

2. Device according to claim 1, characterized in that the lens elements (4, 5) or the mirror elements have a cross section (7) in a central region, which essentially has an aspherical cross section of second order, such as a hyperbolic or a parabolic cross section ( 6) corresponds.

3. Device according to one of claims 1 or 2, characterized in that the lens elements (4, 5) or the mirror elements in their edge regions have a cross section (7) which deviates from an aspherical cross section (6) of the second order.

4. Device according to one of claims 1 to 3, characterized in that the lens elements (4, 5) or d the mirror elements in their edge regions have a cross section (7) of higher orders of a polynomial, in particular of higher straight orders of a polynomial is dominated.

5. Device according to the preamble of claim 1, characterized in that each of the lens elements (4, 5) or the mirror elements is provided with a wavy or sinusoidal structure.

6. The device according to claim 5, characterized in that the periodicity of the structure is smaller, in particular small compared to the periodicity with which the individual lens elements (4, 5) or mirror elements are arranged side by side.

7. Device according to one of claims 5 or 6, characterized in that each of the lens elements (4, 5) or mirror elements has a basic structure underlying the wavy or sinusoidal structure, which is spherical or aspherical second order.

8. A method for producing a device for optical beam homogenization with at least one optically functional interface through which a beam to be homogenized can pass or on which a beam to be homogenized can be reflected, as well as a plurality of lens elements (4, 5) or mirror elements are arranged on the at least one optically functional interface, characterized by the following method steps: a device for optical beam homogenization with at least one optically functional interface and a plurality of lens elements (4, 5) or mirror elements on the optically functional interface is produced; the light distribution of light passing through a single one of the plurality of lens elements (4, 5) or from a single one of the plurality of mirror elements is determined; a structure is applied to each of the lens elements (4, 5) or the mirror elements, which is complementary to the light distribution determined.

9. The method according to claim 8, characterized in that the applied structure in the edge regions of the lens elements (4, 5) or the mirror elements has a greater amplitude than in the central region of the lens elements (4, 5) or the mirror elements.

10. The method according to any one of claims 8 or 9, characterized in that the lens elements (4, 5) or mirror elements produced in the first method step have a regular cross section, in particular a spherical or aspherical cross section of the second order.