HU189042B - Band-pass interference filter - Google Patents

Abstract

The invention relates to interference filters with a pass band for use in optical arrangements and devices for the UV, VIS and NIR range. The aim of the invention is to increase the quality of these interference filters. The object of the invention is to provide interference filters with a reduced absorption band structure and thereby increased transmission in the passband while maintaining a high blocking effect of the paging areas. It has been solved by an interference layer system in that the number of individual layers around the outer layers is reduced in at least one outer filter layer group of the interference layer system compared to at least one inner filter layer group and / or the optical layer thickness of the middle single layer of at least one outer filter layer group is less than the optical thickness is the middle single layer of at least one inner filter layer group.

Description

(57) EXTRAS

The proposed band-pass interference filter having a layer structure of interference applied to a light-transmitting carrier sheet. The layer structure consists of a plurality of stacked groups of symmetrically arranged filter layers between which intermediate layers are arranged. The refractive indices of the light-transmissive non-metallic layers of the layer groups are different, and their optical layer thickness is a quarter of the central filter wavelength, respectively. an integer multiple of twice the central filter wavelength. The essence of the proposal is that the interference layer structure is one or more. the number of layers in several outer layer groups is less than one, respectively. the number of layers in multiple inner layer groups and / or one or more layers. in several outer layer groups, the optical layer of the middle layer is less than one; optical thickness of the middle layer of multiple inner layer groups.

4.2 4.4 4.0 0.9 0.Ö 0.7

-1189,042

The present invention relates to a bandpass interference filter having a bandwidth of 3 to 30 percent of the center bandwidth of the bandwidth.

Such filters are used for resolution of finite spectral ranges and for optical arrangements and devices in the ultraviolet, visible and near infrared ranges.

It is known that band-pass interference filters have a layered structure, metallic and non-metallic, respectively. they consist only of non-metallic layers arranged on a light-transmitting substrate. Layers with a "block filter" function protect the layers from external influences.

The German Patent "716153" known interference filters consisting of a transparent metallic or non-metallic layers, these shortcomings in that the transmission of the metallic layers áteresztősávi opacity, _strength: greatly decreased. German Patent No. 913005 discloses interference filters having a light structure, non-metallic, alternately high and low refractive index. Their maximum throughput transmission is very good due to the low absorption of non-metallic layers.

However, many applications have the disadvantage that the high transmission range is limited to only a narrow wavelength band.

Widening the permeability range by reducing the number of layers causes an unacceptably high barrier transmission of light and results in deterioration of the slope of the perimeter band boundaries. By combining a plurality of filter elements having a small number of layers and therefore a wide transmission range, a so-called "Multiple Cavity Filter" is obtained, which has a low transmittance light transmission and a wide transmission band bounded by steep edges. Knittel describes such a solution in his work "Optics of Thin Films" (John Wiley and Sons, London-New York 1976).

However, when connecting more than three filter elements, there are significant disadvantages of the latter solution. In the pass band, an absorption band structure is formed which impairs the transmission. A further disadvantage is that this band structure is extremely sensitive to manufacturing layer thickness defects.

Also known is a bandpass interference filter, which is produced by combining a wide bandwidth shortwave filter with a wide bandwidth longwave filter so that the common bandwidth of the bandwidths defines a wavelength band. (Thin Films Optical Filters, by H. A. Macleod (Adam Hilger LTD, London 1969, p. 154))

Such a solution is mentioned in the German Patent No. 6369.

The drawback of the bandpass interference filters implemented on the basis of the above principle is that they require two different filters and different layer structures, thus requiring more effort, and the spectral accuracy due to the addition of manufacturing errors of the two filters is insufficient.

It is an object of the present invention to overcome the aforementioned deficiencies of band-pass interference filters, i.e. to improve quality.

Accordingly, the object of the present invention was to provide an optical band-pass interference filter which has a good transmission due to the elimination of the band-pass absorption structure, but this has the other advantageous filtering characteristics, e.g. does not adversely affect the proper bandwidth of the bandwidth and the large bandwidth attenuation within the band boundaries.

The object of the present invention is solved by a band-pass interference filter having a layer structure of interference applied to a light-transmitting substrate covered with a glued cover glass sheet. The layered structure has a plurality of arranged symmetrical structures, e.g. g2H, Hg2NH, HNg2HNH; or HNHg2NHNH is a layer filter group. Intermediate N layers are located between the layer groups. The light-transmissive non-metallic layer groups Η, N or g2H, g2N layers of N 'and _N refractive index n different. Their optical layer thickness is a quarter of the central filter wavelength λ „and an integer multiple of g twice g λ, / 4 (g = 1, 2, 3).

This was achieved by reducing the number of layers of one or more outer layer groups in the interference layer structure by omitting the outer layers H and N, respectively, and / or the middle g2H and g2N of one or more inner layer groups, respectively. The optical layer thickness of the layers is less than the optical layer thickness of the middle layer of one or more inner layer groups. It is further preferred that N, or N. refractive index of g2N layers and H and L, respectively. The refractive index of g2H layers is different. Furthermore, it is also preferable if the intermediate layer N n _F the refractive index n _r is the same for the carrier and affixed to cover this glass plate of refractive index n _R. If they have different refractive indexes, there may be an additional N layer between the carrier sheet and the interference layer structure and / or between the layer structure and the glued cover glass sheet.

It is an object of the present invention that at least one outer layer group of the interference filter layer structure differs from one or more inner layer groups of the same layer structure in that the number of H and N layers and / or the middle layers is smaller.

The term "outer layer group" refers primarily to the lowest layer group on the backing sheet and to the highest layer under the cover glass, but may also include second or lower layer groups.

Preferably, the outer layer groups differ from the inner layer groups of the same layer structure only in that they have two outer layers H and N having an optical layer thickness of XJ4 and / or reduced by 2H and 2N layers in the middle g2H and g2N layers, respectively. As a result, the optical layer thickness of the outer layer group is λο / 2 smaller than that of the inner layer group.

An advantage of the interference layer structure according to the invention is that it can eliminate or greatly reduce the absorption band structures which adversely affect the filter pass band, thereby improving transmission. Other filter features such as. bandwidth and end-band attenuation remain unchanged.

As a carrier sheet or as the cover glass, commonly used glass sheets, which

In addition, -2189 042 have filtering effects known per se.

The invention will be described in more detail with reference to the drawing.

In the drawing:

Fig. 1 is a schematic transmission diagram of a known interference filter;

Figure 2 is a schematic diagram of a spectral transmission diagram of an embodiment of the present invention;

Fig. 3 is a spectral transmission diagram of another known interference filter;

Figures 4, 5 and 6 show a spectral transmission diagram of a further embodiment of an interference filter according to the invention.

The spectral transmission in the drawing is given in the form of λο / λ waves relative to the central wavelength of the transmission band. λ _{0 can be} properly selected and considered as a unit wavelength, since the optical layer thickness of the H and N layers is 1/4 λν ·

By determining the appropriate central wavelength λ <, where appropriate, the optical layer thickness of each layer is also given.

Figures 2, 4 and 6 show the wavelength scale as an illustration. for λθ = 55Ο nm. In this particular case, the optical layer thickness of each of the H and N layers is 1/4 λ <, = 137.5 nm, and the optical layer thickness of the middle g2H and g2N layers is a multiple of 2g.

The invention will now be described in more detail with reference to the following embodiments:

Embodiment 1

In Embodiment 1, the starting point is a known interference filter, which is modified according to the invention. The known layer structure: It is composed of two identical groups of layers G ₂ = H2NH. The layer groups are arranged on top of each other on a glass substrate, with N layers arranged between them and covered with a glued cover glass sheet. The symbol structure of the layer structure is as follows:

Substrate (NG ₂ NG ₂ NG NG _{2 2 2} NG NG NG _{2 2} N) covers the glass sheet where

N: cryolite or intermediate cryolite, refractive index: n _N = 1.30

H: zinc sulfide layer, refractive index: n _H = 2.36

The optical layer thickness of the H and N layers, respectively. 1/4 λο. The optical layer thickness of the 2N inner layers (g - 1) of the groups G _{2 is} accordingly 1/2 λθ. It follows that the optical layer thickness of the three layers is always λθ.

The transmission diagram of this known interference layer structure is shown in Figure 1. The figure shows the errors in the throughput bar. In extreme cases, transmission may be reduced to T = 0.5.

This known layer structure was changed in accordance with the invention in that the two G ₂ rétegsoport the two outer replaced with the simplest, G = 2 H layer group, AG, layer group is actually a half λθ optical thickness layer. The interference layer structure according to the invention is thus symbolically represented as follows:

cover sheet (NG ₁ NG ₂ NG ₂ NG ₂ NG ₂ NG _J NG ₁ N) cover glass

The spectral transmission is shown in Figure 2.

As can be seen in the figure, the known interference layer structure band structure errors (FIG. 1) have been largely eliminated by the present invention, while other filtering features, such as the filtering feature, are eliminated. throughput bandwidth and end-band attenuation remained unchanged.

Embodiment 2

Similar to Embodiment 1, the interference layer structure known in Embodiment 2, which is symbolically denoted by:

cover sheet (NG ₃ NG ₃ NG ₃ NG ₃ NG ₃ N) cover glass

The layer structure comprises five identical groups of layers G1 = HN2HNH, each consisting of five layers. The layers have the same basic material as those described in Example 1.

Figure 3 shows the band structure errors of the filter throughput range.

According to the present invention, this layer structure has been altered by replacing both outer layer groups G _{3 with a} group G ₂ -H ₂ NH. This reduced the number of layers in the outer layer groups by omitting two 2H layers.

Symbolic notations of the new layer structure:

cover sheet (NG ₂ NG ₃ NG ₃ NG ₃ NG ₂ N) cover glass

As shown in Fig. 4, the bandwidth transmission was improved by eliminating interfering absorption bands.

Embodiment 3

As with Examples 1 and 2, consider the following symbolic designation of the interference filter of the present invention:

cover sheet (G ₃ NG ₄ NG ₄ G ₃ ) cover sheet with G ₄ = HN4HNH and G ₃ = HN2HNH

The layers have the same basic material as those described in Example 1.

In this embodiment, the optical layer thickness of the middle 2H (g = 1) layer of the two outer G ₃ layers is less than 1/2 λθ than the two inner G ₄ layers.

-3189 042 is the optical layer thickness of the middle 4H (g = 2) layer of the layer group.

As shown in Figure 5, the spectral transmission diagram of the filter does not show bandwidth imperfections in the through-band.

Embodiment 4

Using the layer materials of Exemplary Example 1, the interference layer structure of the present invention is symbolically designated as: a backing sheet (G ₃ NG ₃ NG _S NG ₃ NG ₃ ) cover sheet wherein G ₃ = HN 2 H N G _S == HNH 2 NHH

So G ₃ is made up of five layers and G _} is made up of seven layers.

Figure 6 shows that this solution does not show bandwidth errors in the bandwidth.

Claims (6)

First band pass interference filter, which is permeable support sheet is can be covered with bonded cover glass plate, a symmetrical design of each other arranged layers of groups which are linked by N intermediate layer and the layer groups of light-transmissive non-metallic Η, N or g2H, g2N of layers of n 'and n _M the refractive index different and have an optical layer thickness of one quarter of the center filter wavelength (λο) or multiple of _g of g λθ / 4 (g = 1, 2, 3), characterized in that the number of layers in one or more outer layer groups of the interference layer structure H, respectively. less than one due to leaving N layers, respectively. number of layers in multiple inner layer groups, and / 1 n ^v ag.v The optical thickness of the middle layer, g2H, or g2N, in one or more inner layer groups is less than the optical thickness of the middle layer of one or more inner layer groups. The interference filter of claim 1, therewith 15, characterized in that the refractive index of the N and g2N layers is lower than that of H and g2N, respectively. g2H layers. Interference filter according to claim 1, characterized in that the refractive index of the N and g2N layers is higher than that of the H and g2H layers, respectively. 2o Interference filter according to claim 1, characterized in that the interlayer N layers have n _N , the carrier sheet n _T and the glued cover glass sheet have the same refractive index n _K. The interference filter of claim 1, wherein Characterized in that, in the event of a difference in refractive index between the interlayer N layers, the carrier sheet and the glued cover sheet, there is provided ₃₀ additional intermediate N layers between the interlayer and the interference layer structure and / or the glued cover sheet. 6 pieces of figure -4189.042 -5189 042 -6189 042