DE10047682A1 - Optical multiplexer or demultiplexer for adjusting an optical element such as interference filter, includes two mutually rotatable adjustment elements - Google Patents

Abstract

A device for adjusting an optical element, especially an interference filter, includes a first adjustment element (25) for retaining the optical element (5) for adjustment, a second adjustment element (27) resides in a mounting plane (E) with one front face on a mutually interacting front face of the first adjustment element (25), in which the mounting plane (E) extends non-parallely to the optical plane (O) of the optical element (S). The first adjustment element (25) and the second adjustment element (27) are mutually twistable/rotatable, in which the axis of twist/rotation runs parallel to the vector of the normal on to the mounting plane (E).

Description

The invention relates to a device for adjusting an optical element, in particular special of an interference filter, the plane of the optical element being such is pivotable that the light striking the optical element with the Nor paint on the optical element includes a predetermined angle of incidence (Pa Claim 1). Furthermore, the invention relates to an optical device, in particular special an optical multiplexer or demultiplexer, which using such a device for adjusting an optical element is constructed (Claim 6). Finally, the invention relates to a method for producing the optical device according to the invention (claim 8).

In practice, the design and adjustment of optical elements is common the problem that the plane of an optical element to be adjusted, for example an interference filter, must be adjusted so that the incident light passes included incidence angle with the surface normal of the optical element. This allows a corresponding beam path of a reflected or transmit Tiert light beam can be achieved, the optimal coupling to other optical Facilities or elements, such as optical fibers, guaranteed.

The use of devices which allow a direct pivoting of the to justie renden optical element around one or two pivot axes problematic, since usually only very small adjustment angles are required to the to enable the desired optimal adjustment. This in turn requires adjustment mechanics that set extremely precisely within a correspondingly small angular range is cash. Such adjustment devices have so far been structurally complex and thus expensive.  

Furthermore, there is a practical test in the production of interference filters lem that the high-precision observance of the center wavelength measured in transmission faded bandpass characteristics or the bandstops relevant in reflection characteristic due to the small permissible tolerances only with great effort is possible or that when using smaller manufacturing tolerances a high outside chußrate is generated.

For this purpose, it is known in the case of interference filters that the center wavelength is in one practice can often shift sufficient range when the interference filter is inserted obliquely into the beam path of the light to be filtered. With other wor ten, by adjusting the angle of incidence or the "inclined position" of the plane of the interior reference filter relative to the beam path can be on in a predetermined range the center wavelength of the filter. Again, this is a high exact adjustment of the plane of the optical element in the form of the interference filter required to ensure a given angle of incidence of the light to be filtered Afford.

Starting from this prior art, the invention is based on the object a device for adjusting an optical element, in particular an interface renzfilter, to create, which in a simpler way, the exact setting of the opti level of the optical element. Furthermore, the invention is the The underlying task is to create an optical device in which the optical level of an optical element can be adjusted so that a predetermined incidence angle for the light impinging on the optical element and accordingly optionally a predetermined optical property dependent on the angle of incidence of the optical element is adjustable. Finally, the invention has the object Basically a simple and inexpensive method for producing such to create optical equipment.  

The invention solves this problem with the features of claims 1 and 6, respectively or 8.

The invention is based on the knowledge that a device for adjusting the optical level of an optical element there in a simple and inexpensive way can be realized by using a first and a second adjusting element the end faces of which lie against one another in a plant level. In the first adjustment element is an adjusting optical element held so that the optical plane of the optical element is not parallel to the contact plane. In other words, the surface normals on the contact level and the optical level of the optical ele elements must include a non-zero angle. The adjustment of the idea Angle on the optical element can then be done in a simple manner that the first and second adjustment element are rotated against each other, the rotation axis runs parallel to the normal vector on the contact plane.

The greater the angle that the surface normals enclose, the more the area in which the angle of incidence is adjusted on the optical element is larger can be. Since in practice there is often an adjustment range for the angle of incidence of a few degrees will suffice, a relatively small angle between the opti level of the optical element and the system level can be used. Dement speaking, there is a relatively large "mechanical reduction" of Adjusting device, d. that is, a large angle of rotation of the two adjusting elements against one another it causes only a relatively small change in the angle of incidence. This will help with the very constructive device according to the invention a highly accurate jus the angle of incidence.

The first and second adjusting element are according to the preferred embodiment Invention essentially hollow cylindrical. The optical element can in the interior of the first adjustment element or on that facing away from the contact plane Be held front of the first adjusting element. The adjustment elements can be extremely  simply made by cutting a single hollow cylindrical element the cutting plane, which defines the later investment plane, in one certain angle to the axis of the hollow cylindrical element is selected.

The adjustment elements exist at least in the areas of the plant level end faces made of a bondable, weldable or solderable material al. In particular, the adjustment elements can consist of metal, so that the adjustment elements after completing the adjustment process (relative rotation of the adjustment elements to each other) can be connected to each other by laser welding. here this results in a particularly simple and cost-saving set-up and adjustment gear.

According to one embodiment of the invention, the adjusting device can comprise means sen, which cause the first and / or second adjustment element with the respective Face-to-face contact at the plant level. This also results when the adjusting elements are rotated relative to one another, a defined position.

The faces of the adjustment facing away from the faces defining the contact plane elements can be designed in such a way that they can be easily combined with other elements directions, in particular one or more optical waveguide coupling device lines and / or other optical elements containing devices, connectable are.

Such an adjustment device can be used to implement an optical device, serve in particular an optical multiplexer or demultiplexer, the optical device has two coupling devices, the adjustment on both sides direction are provided. The coupling devices can each have one or more Optical fibers and / or further optical elements include. Furthermore point the coupling devices means for adjusting and fixing the optical waveguide and / or means for adjusting and fixing the further optical elements relatively  to the adjustment device. The means in question can be adjusted in a level ne enable to be adjusted essentially parallel to the optical plane of the optical element runs (adjustment in the lateral direction). Alternatively or additionally Lich the means can be adjusted in a direction perpendicular to the optical plane enable the optical element to be adjusted. Adjusting the optical fibers and / or the further optical elements in a plane parallel to the optical plane of the optical element can both by a transversely shifting the Lichtwel conductor in the direction of the plane as well as by a rotary movement of two or more connected optical fiber or other optical elements around an axis take place parallel to the axis of one of the optical fibers or to the axis of one of the optical elements runs.

Instead of the means that an adjustment of the optical fiber or the other opti allow elements, a corresponding adjustment of the coupling directions take place relative to the adjusting device. After finishing a law animal process then the relevant means or the coupling devices in the achieved optimal adjustment position fixed.

The adjustment of the coupling devices by lateral displacement, twisting and / or axial displacement of the coupling devices is preferably carried out in such a way that a maximum transmission of light during the transition from the adjustment device into the Optical waveguide or in the other optical elements is reached. same for of course for adjustment by means of jus provided in the coupling device animal forward.

Further embodiments of the invention result from the subclaims.

The invention is described below with reference to an embodiment shown in the drawing example explained in more detail. Show in the drawing  

Fig. 1 shows a schematic longitudinal section through an optical device in the form of an optical multiplexer or demultiplexer,

Fig. 2 is a schematic longitudinal section of the adjustment device used for the optical device in Fig. 1 in a second adjustment position and

Fig. 3 is a schematic representation of the band-pass characteristic of to adjust the optical element, and the spectrum of the input signal of the optical rule means in FIG. 1.

Fig. 1 shows an optical device 1, which is designed as an optical multiplexer / demultiplexer. In its central region, the optical device 1 comprises a device 3 for adjusting an optical element 5 , which in the specific case can be designed as an interference filter. A coupling device 7 , 9 is provided on both sides of the adjusting device 3 . The coupling device 9 essentially consists of a hollow cylindrical part 11 , in which a further optical element 13 is provided, which can preferably be designed as a gradient lens (GRIN). Furthermore, the ends of two light waveguides 15 , 17 are held in the hollow cylindrical part 11 , the end faces of which are coupled to certain positions on the end face of the further optical element 13 . For this purpose, the optical waveguides can either be glued to the further optical element 13 or (not shown) in separate holders.

The further optical element 13 and / or the optical waveguides 15 , 17 can be adjustable within half predetermined areas in the hollow cylindrical part 11 . The adjustment can take place in such a way that the optical fibers 15 , 17 can be rotated together with the further optical element 13 about an axis which runs parallel to the longitudinal axis A of the optical device 1 . For example, the rotation about the longitudinal axis of the optical waveguide 15 can take place, so that when the further optical element 13 and the optical waveguides 15 , 17 are adjusted, the beam path between the front end of the optical waveguide 15 and the optical element 5 remains constant. The front end of the optical waveguide 17 is correspondingly tracked when the further optical element 13 and the optical waveguides 15 , 17 are rotated about the longitudinal axis of the optical waveguide 15, a course of the reflected beam changed by the adjustment of the optical element 5 . (compare below)

The coupling device 7 on the other side of the adjusting device 3 also consists of a hollow cylindrical part 19 , in which in turn a further optical element 13 , preferably in the form of a GRIN, is provided. Furthermore, the end of a further optical waveguide 21 is held in the hollow cylindrical part 19 . This is coupled to the end face of the optical waveguide 21 at a predetermined position on the end face of the further optical element 13 .

Fig. 1 shows schematically the beam path within the optical device 1, when operated as an optical wavelength demultiplexer. For this purpose, an optical signal is coupled into the optical waveguide 15 , the partial signals of which have the carrier wavelengths λ ₁ to λ _n . The light emerging from the end face of the optical waveguide 15 is fed to the optical element 5 to be adjusted by means of the further optical element 13 in the form of the GRIN. The light strikes the optical element 5 at a predetermined angle of incidence. Since the optical element 5 is designed as an interference filter, which acts as a bandpass filter with a predetermined center wavelength Λ _k for the transmitted light, it can be achieved that only that partial signal is coupled into the end of the optical waveguide 21 which has the carrier wavelength λ _k . The prerequisite for this is, of course, that the center wavelength Λ _k and the bandwidth of the interference filter 5 are selected such that essentially the entire spectral power of the partial signal with the center wavelength λ _k lies within the bandpass range of the interference filter 5 . Furthermore, the end of the optical waveguide 21 must assume a position in which an optimal coupling (maximum transmission) of the light or partial signal transmitted by the interference filter 5 with the central wavelength λ _{k is} ensured. The remaining part of the total signal is reflected on the surface of the interference filter 5 in accordance with the law of refraction and is coupled via the GRIN 13 into the end of the optical waveguide 17 . Of course, the end of the optical waveguide 17 must be positioned with respect to GRIN or the optical element 13 so that the remaining signal, which the partial signals with the carrier wavelengths λ ₁ . , , λ _k-1 , λ _{k + 1} . , , λ _n , is coupled into the optical waveguide 17 with maximum transmission.

As already explained above, the center wavelength Λ _{k of} the optical element 5 designed as an interference filter depends on the angle of incidence. Thus, by pivoting the optical plane O, which leads to a change in the angle of incidence, a shift in the center wavelength Λ _k and thus a shift in the bandpass range of the interference filter 5 can be achieved in a certain range.

This principle is shown schematically in FIG. 3. The curve 23 in FIG. 3 shows the bandpass curve of the interference filter 5 (in relation to the transmitted light) and an extract of the spectrum of the total signal coupled into the optical waveguide 15 (curve 29 ) at the carrier wavelengths λ _k-1 , λ _k and λ _{k + 1} , the filter 5 being detuned from the partial signal at the center wavelength λ _k . The detuning is so great in the example shown that practically no power of the partial signal at the carrier wavelength λ _k passes the filter. In order to achieve that the partial signal with the central wavelength λ _{k is} coupled into the optical waveguide 21 , the angle of incidence of the light when it strikes the optical element 5 must be changed so that the filter characteristic moves in the direction of higher wavelengths. The optimum angle of incidence is achieved when the filter center wavelength Λ _k with the carrier wavelength λ _k matches or if it is ensured, is that the entire spectral power of the sub-signal within the band pass range of the interference filter 5 is located.

The shift of the center wavelength of the optical element 5 can be achieved according to the invention in that the adjusting device 3 has a first and second adjustment element 25 , 27 . The first and second adjusting element are each designed so that the opposing end faces abut one another in a bearing plane E. The contact plane E is selected such that the surface normal to the contact plane E includes a predetermined angle α with the optical plane O of the optical element. In the situation shown in FIG. 1, the two planes O and E each run perpendicular to the plane of the drawing.

By rotating the first adjusting element 25 relative to the second adjusting element 27 , a change in the angle of incidence of the light striking the optical element 5 can be achieved, which results in a shift in the filter characteristic or the center wavelength Λ _{k of} the bandpass range of the optical element 5 ,

The geometric situation shown in FIG. 1 can lead to the situation shown in FIG. 3, in which the filter characteristic is "completely" detuned from the signal to be filtered. Curve 29 for the spectrum of the entire signal is shifted so far compared to curve 23 for the filter characteristic at an angle of rotation α _v that practically no power of the partial signal to be filtered out in the desired manner is coupled into the optical waveguide 21 with the carrier wavelength λ _k .

In contrast, FIG. 2 shows the adjusting device 3 from FIG. 1 with a first adjusting element 25 rotated by an angle α _opt with respect to the second adjusting element 27 . At the optimal angle of rotation α _{opt it} is achieved that the angle of incidence of the light impinging on the optical element 5 is changed such that the center wavelength Λ _{k of} the filter characteristic matches the center wavelength of the partial signal with the carrier wavelength λ _k .

Since the first and second adjusting element 25 , 27 of the adjusting device 3 can be produced by obliquely cutting a hollow cylinder, this results in a very simple and cost-effective possibility for adjusting an optical element 5 in such a way that a desired angle of incidence for the the optical element 5 results in incident light.

The adjustment process by means of the adjustment device 3 when producing the wavelength multiplexer / demultiplexer according to FIG. 1 can be carried out as follows: Measuring light with a broadband spectrum is coupled into the optical waveguide 15 . The light transmitted through the optical element 5 is detected with regard to its spectral profile and the center wavelength Λ _{k of} the filter characteristic is determined. In the event of a deviation of the current center wavelength from the desired center wavelength of the filter characteristic, the first adjusting element 25 is rotated until the desired center wavelength of the filter characteristic results as a result of a changed angle of incidence. In this case, instead of coupling light into the optical waveguide 15, the measuring light can also be supplied directly, ie with the coupling device 9 omitted, to the optical element 5 in such a way that the same beam path results in the area in front of the optical element 5 as if light using the coupling device 9 when coupling in the optical waveguide 15 would be used.

The adjustment position of the adjusting member 27 is the desired adjustment position upon rotation of the first adjusting element 25 relative to the second adjusting element reaches 27, it is fixed elements, for example by welding the group consisting of plastic, glass, or metal hollow cylindrical adjusting elements 25.

For this adjustment process, instead of coupling the transmitted light into the optical waveguide 21 , the coupling device 7 is also missing and the measuring light can be detected by means of a suitable, large-area photodiode, so that readjustment of the photodiode due to the small offset of the transmitted beam when the angle of incidence changes is not required.

In a next step, the coupling device 9 can then be adjusted so that when light is supplied via the optical waveguide 15, the light reflected on the optical element 5 is optimally coupled into the optical waveguide 17 . Since a change in the position of the optical plane O of the optical element 5 primarily changes the spatial direction of the reflected beam, an adjustment can be made in that the coupling device 9 is rotated about the axis of the optical waveguide 15 until an optimal coupling of the reflected light in the light waveguide 17 results. In addition, a transverse displacement of the optical waveguide 17 (or its end face) on the rear end face of the GRIN 13 may be required, since the change in the angle of incidence also causes a change in the radial position of the exit point of the reflected beam on the rear end face of the GRIN 13 becomes. Instead of a rotation of the coupling device 9 about the axis of the optical waveguide 15 , only an adjustment movement of the optical waveguide 17 can be provided in the plane of the rear end face of the GRIN 13 . In addition, an adjustment of the GRIN 13 in the axial direction of the Koppelvor direction 9 may be necessary since there is also a change in length of the optical path between the two ends of the optical fibers 15 , 17 when the angle of incidence changes.

The adjustment of the GRIN 13 and the optical waveguide ends 15 , 17 can also be so successful that the hollow cylindrical part 11 of the coupling device 9 is connected to the adjusting device 3 from the outset. In this case, the GRIN 13 and optical fibers 15 , 17 can then be adjusted within the hollow cylindrical part 11 . Here, means familiar to any person skilled in the art can be used.

In both cases, the coupling device 9 can be fixed to the adjusting device 3 or the GRIN 13 and the optical waveguides 15 , 17 can be fixed by gluing, soldering or welding. For this purpose, the GRIN 13 and the optical waveguide ends 15 , 17 can be held in separate parts, not shown, which can be welded to one another or to the hollow cylindrical part 11 .

In a further step, the attachment or adjustment of the coupling device 7 can then take place in a corresponding manner on the opposite side of the adjusting device 3 . The adjustment of the GRIN 13 or the optical waveguide 21 can be carried out in the same manner as was previously described in connection with the coupling device 9 . Since only one optical waveguide is provided in the coupling device 7 in the exemplary embodiment shown in FIG. 1, the adjustment process is correspondingly simpler. It is only necessary to ensure that the lateral position of the optical waveguide 21 and possibly the axial position of the GRIN 13 is selected in such a way that an optimal decoupling (with respect to maximum transmission) of the light transmitted by the optical element 5 into the Lichtwel lenleiter 21 results.

Claims (10)

1. Device for adjusting an optical element, in particular an interference filter, characterized in that

• a) that a first adjusting element ( 25 ) is provided, in which the optical element ( 5 ) to be adjusted is held,
• b) that a second adjusting element ( 27 ) is provided, which lies in a system plane (E) with an end face on a cooperating end face of the first adjusting element ( 25 ), the contact plane (E) not parallel to the optical plane ( 0) of the optical element (S) runs, and
• c) that the first adjusting element ( 25 ) and the second adjusting element ( 25 ) can be rotated relative to one another, the axis of rotation running parallel to the normal vector on the contact plane (E).

2. Device according to claim 1, characterized in that the first ( 25 ) and second ( 27 ) adjusting element are substantially hollow cylindrical and that the optical element ( 5 ) inside the first adjusting element ( 25 ) or on the contact plane (E ) facing away from the first adjusting element ( 25 ) is held. 3. Device according to claim 1 or 2, characterized in that the first ( 25 ) and second ( 27 ) adjusting element consists at least in the areas of the end faces defining the contact plane (E) of an adhesive, weldable or solderable material, preferably of plastic , Glass or metal. 4. Device according to one of the preceding claims, characterized in that means are provided which act on the first ( 25 ) and / or second ( 27 ) animal element in such a way that they rotate relative to each other with the respective end faces in the Contact plant level (E) securely. 5. Device according to one of the preceding claims, characterized in that the end faces of the adjusting elements ( 25 , 27 ) facing away from the end faces defining the contact plane (E) for connection to further devices ( 7 , 9 ), in particular coupling one or more optical waveguides Before devices and / or other optical elements containing devices are formed from. 6. Optical device, in particular optical multiplexer or demultiplexer,

• a) with a receiving device for at least one optical element and
• b) with coupling devices provided on both sides of the receiving device, each coupling one or more optical waveguides and / or containing further optical elements,

characterized,

• a) that the receiving device is designed as an adjusting device ( 3 ) according to one of claims 1 to 5 and
• b) that the coupling devices ( 7 , 9 ) means for adjusting and fixing the optical waveguides ( 15 , 17 , 21 ) and / or the further optical elements ( 13 ) relative to the adjusting device in an essentially to the optical plane (0) of the to be adjusted Optical element ( 5 ) parallel plane (late ral) and / or in a direction perpendicular to the optical plane (0) of the optical element ( 5 ) to be adjusted or that the Koppelvor directions ( 7 , 9 ) themselves can be adjusted and fixed accordingly.

7. Optical device according to claim 6, characterized in that in at least one of the two adjustment devices ( 3 ) provided Koppelvor directions ( 9 ) at least two optical fibers ( 15 , 17 ) are fixed to each other in a fixed position and that the at least two optical fibers together around an axis which is substantially parallel to the longitudinal axis of the Justiervorrich device ( 3 ), rotatable and fixable in the desired position. 8. A method for producing an optical device, in particular an optical multiplexer or demultiplexer, with a receiving device for at least one optical element and with both sides of the receiving device before, each coupling one or more optical waveguides and / or containing further optical elements, coupling devices, thereby in

• a) that an adjusting device ( 3 ) according to one of claims 1 to 5 is used,
• b) that the first adjusting element (25) and the second adjusting element (27) can be adjusted by rotation relative to each other so that the incident angle of the lement in the operation of the optical device (1) to the optical-to-move E (5) the incident light a predetermined Has value, and
• c) that the two adjusting elements ( 25 , 27 ) are fixed in the adjusting position.

9. The method according to claim 8, characterized in that the Koppelvorrich lines ( 7 , 9 ) laterally and / or axially adjusted to achieve a maximum transmission when the light from the adjusting device ( 3 ) in the optical waveguide ( 15 , 17 , 21 ) and be fixed in the adjustment position. 10. The method according to claim 8 or 9, characterized in that the fixing of the adjusting elements ( 25 , 27 ) and / or the coupling devices ( 7 , 9 ) by gluing or welding, preferably laser welding, takes place.