DE19750901A1 - Multimode optocoupler and method for its production - Google Patents

Abstract

A multi-mode optical coupler comprises first 100 and second 140 optical fibers composed of the plastic clad fiber or the plastic fiber, an optical transmission medium 110 placed between the first and second optical fibers and connected to the first and second optical fibers, a channel transmission path 130 which has a space in which the first and second optical fibers are placed and the optical transmission medium 110 is filled between the first and second optical fibers, and which outputs a transmission light after the space is filled with the optical transmission medium 110, and a cover 120 which aligns the first and second optical fibers and is placed on the channel transmission path 130. The optical transmission medium maybe a resin. A third optical fibre may be joined as above (Fig.2).

Description

The invention relates to an optocoupler with a optical plastic fiber or an optical fiber with Plastic jacket and in particular a multimode optocoupler with low loss optical transmission, in which the light, that by an optical plastic fiber or an optical Fiber with a plastic jacket goes into an optical transmission medium falls in a channel transmission path and then from an optical fiber is output that corresponds to the optical Transmission medium is arranged opposite, as well as a Ver drive to its manufacture.

The propagation of light through reflection and bre chung is due to the angle of incidence of the light and the bre index determined by two media. An optical fiber is a medium that has a powerful light propagation allowed. An optical fiber consists of an inner core, that transmits the light, and from a coat with one  other refractive index such that the light in the core is total is reflected. Usually a core with a Diameters from about 8 µm to 62.5 µm used to light in an optical quartz fiber to transmit, as this out has drawn optical properties, compared to environmental is stable and heat stable. Because of the small However, the diameter of the core results in considerable tech difficulties in connecting optical fibers with each other or when branching or uncoupling and combi kidney or coupling the transmitted light. In the recently there has been a sharp increase in usage of optical fibers with plastic sheath and optical Plastic fibers in optical communication systems given a suitable bandwidth tandem distance ha ben.

An optical fiber with a plastic jacket has one Quartz glass core, which is surrounded by a plastic jacket, with a big difference between the core and the jacket Refractive power. Optical fibers with plastic sheath are used in particular as an optical data connection link used because it has a large diameter, a high one numerical aperture and excellent loss characteristics to have. Silicon is used as a conventional sheath material resin related. But it is already an optical fiber developed with a plastic jacket made of a hard fluoroacrylic resin been. Optical fibers with a plastic jacket often related to a compression process called Fiber attachment method of an optical connector Attention that assembled on the spot becomes. Furthermore, the temperature characteristics of the Transmission loss of optical fibers with plastic coat cheaper. A commonly used optical fiber with plastic jacket has a core diameter between  110 µm and 200 µm and a high numerical aperture of 0.37. The optical fiber with a plastic jacket described above is particularly suitable for use in optical night straightening transmission systems because they have a damping factor of 6 dB / km with respect to an incident wavelength of 850 nm Has. Currently, a plastic sheath fiber with a Transmission loss of 5 to 7 dB / km and a transfer range from 5 to 10 Mhz.km used. The one described above optical fiber with plastic jacket is called short haul Data link with 1 km or less, for the picture transfer, etc. applied.

Optical plastic fibers have an excellent Flexibility, a cheap core diameter and a good one numerical aperture, they are also ver with low cost bound, so that they quickly the conventional optical Have replaced quartz fibers in local networks. A common one optical plastic fiber consists of polymethyl methacrylate (PMMA) or polystyrene. In recent times there have been attempts with polycarbonate, a thermosetting polymer, with fluorpo lymeren and performed with silicon compound. The About Carrying losses of an optical plastic fiber are in the generally in the range between 160 and 1000 dB / km and zei their lowest value in the 600 nm range. Most recently Time is usually an optical plastic fiber ver that turns a total loss in the range between 1300 and 1500 nm. The numerical aperture of the optical plastic fiber is up to 0.6 and it is an application with an inexpensive LED possible. The biggest before Part of an optical plastic fiber is in particular in that it has a diameter of up to 3 mm can be put.

An optocoupler that uses an optical Fiber is manufactured is a facility for input or  Coupling an optical signal. The coupling or Decoupling an optical signal in optical messages connection systems is the basic function of configura tion of various optical communication networks, like it is similar when coupling and decoupling electrical Communication systems is. Coupling in or out of an electrical signal can be done simply by a mechanical connection of copper wires, the Coupling in and out of optical signals is in this simply not possible what is on the characteristics of optical fibers. It therefore becomes an optocoupler ver as a separate optical coupling and decoupling device turns.

So far, to a large extent, since the 1970s The optocoupler with optical fiber used is a welded one ter coupler, that of the coupling with decaying field Makes use of. This creates a welded coupler represents that several optical fibers are twisted together and the twisted optical fibers simultaneously welded and tensioned. Any dielectric mono the waveguide with optical fibers has a decaying electromagnetic field that expose from the nucleus to the outside tially decreases. So if two single-mode waveguides next to lie next to each other, a waveguide mode through the clipping field of neighboring nuclei is stimulated and occurs Coupling of the optical signals. Such a coupling is called coupling with decaying field, which at a welded and tensioned coupler is used. One of the like coupler, however, makes a complicated and time-consuming Manufacturing process required and is high Associated costs, but it is not likely that remove them in the future.

Another coupler is a waveguide or waveguide  coupler. A waveguide coupler can be a light input and - Execute decoupling function in that a quartz glass waveguide is formed on a silicon substrate, or the waveguide uses an ion exchange glass. Although small couplers are manufactured in large quantities if the waveguide technology is used, there are many technical problems, for example regarding the Losses of the waveguide itself, the fiber coupling ver or with regard to the technical process of Waveguide training.

Another coupler is a so-called direct core expansion coupler having an expansion element that the core of an optical fiber in a channel transmission path enlarged. The expansion element has the function of Expansion of the light transmitted via a core a much larger cross section centered on the core is. Using such an expansion element an optocoupler can be formed. If accordingly several optical fibers with well-cut end faces Chen are put together in order and then Aufwei tion elements from each cross section of the fibers det, take the cross sections of the expansion elements gradually to. Hence, the touch and combine expansion elements each other in a more or less large Distance. If the expansion elements are designed as a body light is coupled in and out. The coupler works a problem-free light connection compared to the ge welded coupler or the waveguide coupler, so that Branching off and connecting optical fibers is easier and decrease the cost of the coupler. The route the core widening in the channel transmission path is so long, however, that the expansion element, which is formed by UV radiation becomes, wobbles or moves easily. The light transfer  loss due to the influence of the resin, that between the fiber cross section and the wall of the channel transmission path is available. The work of the coupler is therefore noticeably impaired so that it is not used by anyone that can.

Next to the optocoupler is the optical connector an essential element of optical communications systems. The optical connector that is an element for coupling optical fibers, facilitates the recursive Connection. So far, different optical types have been used connecting links for connecting optical cables in opti messaging systems including opti related underwater cables. In connection with the The latest technical developments have been the training of optical connectors have been greatly simplified and high-performance optical connectors developed. Optical connectors are too expensive, however bound. The reason for this is that the diameter of the core of an optical fiber is small. Even if only a difference of 1 to 3 µm in the connection of the cores is created by optical fibers together is the opti loss due to this slight difference considerably. Extreme accuracy is therefore required Lich. The required accuracy is then generally even greater if light is from an optical fiber comes, is expanded or extended. It is already developed a method for extending an optical fiber been. The light extension process does however also high accuracy in the assembly of the optical extension device and the optical fiber required.

The invention is therefore intended to provide a multimode optocoupler with a plastic fiber or a fiber with plastic  coat that couples light easily, that into the fiber with plastic jacket or the plastic fiber falls by this by a residual monomer that follows is referred to as resin and an optical transmission medium to be in a channel transmission path, or via a polymer as an optical transmission medium that goes through pre-hardening of the resin is formed, and formed into an optical fiber that will give the plastic fiber or the fiber with art opposite to the material jacket, the optical transmission should be low loss. The optocoupler according to the invention is intended easy branching and coupling of fibers and one allow easy connection between the fibers and the Branch, coupling and connection costs keep low. Through the invention, a Ver drive to manufacture such an optocoupler fen.

To this end, the multimode optocoupler according to the invention comprises a first optical fiber that receives transmission light and from a fiber with a plastic jacket or an art fabric fiber, a second optical fiber that over emits carried light and is made of a fiber with plastic coat or a plastic fiber, an optical Transmission medium between the first and the second optical fiber is arranged and with the first and the second optical fiber is connected to a channel transmission path that has a space in which the first and the two te optical fiber are arranged and in which the optical Transmission medium between the first and the second opti cal fiber is filled, and the transmitted light there after the room with the optical transmission medium is filled, and a cover that the first and the two te optical fiber aligns and on the channel transmission is arranged away.  

The optical transmission medium preferably exists from a residual monomer or a polymer, the core of which Pre-curing under ultraviolet light rays is expanded. The resin of the optical transmission medium has a width index between 1.40 and 1.60.

Another embodiment of the invention Multimode optocoupler includes a first optical fiber, the from a fiber with a plastic jacket or a plastic ser consists of a second optical fiber, which consists of a fiber with a plastic jacket or a plastic fiber, one third optical fiber made of a plastic fiber coat or an optical fiber, an optical Transmission medium that has a Y shape and has one end with the first optical fiber and the other two Ends with the second and third optical fibers each because it is connected, a channel transmission path, the one Has space in which the first, the second and the third opti cal fiber are arranged and in which the optical transmission medium is filled, and the transmitted light there after the room with the optical transmission medium is filled, and a cover that the first, the second and aligns the third optical fiber and on the channel transmission path is arranged.

The inventive method for producing the more modenoptokopplers includes the steps of arranging a optical fiber in the channel transmission path, by opti cal fiber is pressed down, the arrangement of a optical transmission medium on the channel transmission path and attaching the cover to part of the opti fiber and on the optical transmission medium.

The following are based on the associated drawing particularly preferred embodiments of the invention described in more detail. Show it  

Fig. 1 shows the structure of a 1 x 1 multi-mode optical coupler, in which a fiber with plastic coating, or a fiber Kunststof is ordered before a resin as an optical transmission medium,

Fig. 2 shows the structure of a 1 × 2 multimode optical coupler, in which a fiber with a plastic sheath or a plastic fiber is arranged in front of a resin as an optical transmission medium,

Fig. 3 is an isometric view of one side of the 1 × 1 and 1 × 2 Mehrmodenoptokoppler in which a fiber with a plastic sheath or a plastic fiber is arranged in front of a resin as an optical transmission medium,

Fig. 4 is a three-dimensional view of one side of the 1 × 1 and 1 × 2 multimode optocouplers, in which a fiber with a plastic jacket or a plastic fiber is arranged in front of a polymer precured by ultraviolet light rays as the optical transmission medium, and

Fig. 5 is a three-dimensional view of one side of the 1 × 1 and 1 × 2 optocouplers with a U-shaped or V-shaped.

Fig. 1 shows the structure of a 1 × 1 optocoupler, in which a fiber with a plastic jacket, which is larger than the core of an optical communication fiber, or an optical plastic fiber 100 is arranged in front of an optical transmission medium 110 . The 1 × 1 optocoupler has a first optical fiber 100 , a second optical fiber 140 , an optical transmission medium 110 , a channel transmission path 130 and a cover 120 .

The first optical fiber 100 receives transmission light and consists of a fiber with a plastic jacket or a plastic fiber. The second optical fiber 140 outputs the transmitted light and also consists of a fiber with a plastic jacket or a plastic fiber, as is similarly the case with the first optical fiber 100 .

The optical transmission medium 110 is arranged between the first and second optical fibers 100 and 140 . Preferably, a residual monomer is used as the optical transmission medium connected to the first and second optical fibers 100 and 140 . The refractive index of the optical transmission medium 110 is larger than that of the cover 120 , which is arranged on the outside of the optical transmission medium 110 , and larger than that of the rectilinear channel transmission path 130 , so that the transmitted light continuously passes through bundled inside.

The channel transmission path 130 on which the first and second optical fibers 100 and 120 are formed is provided with a space to be filled with the optical transmission medium to be formed between the first and second optical fibers 100 and 140 . The optical transmission path 130 is formed so that the transmitted light can be output after the optical transmission medium is filled in the room. The cover 120 arranges the first and second optical fibers 100 and 140 and is arranged on the channel transmission path 130 .

Fig. 2 shows the structure of a 1 × 2 multimode optocoupler, in which a fiber with a plastic jacket or a plastic fiber is arranged in front of a resin as an optical transmission medium. The 1 × 2 multimode optocoupler shown in FIG. 2 has a first, a second and a third optical fiber 200 , 240 and 250 , an optical transmission medium 210 , a channel transmission path 230 and a cover 220 .

The first, the second and the third optical fiber 200 , 240 and 250 consist of a fiber with a plastic jacket or a plastic fiber. The first optical fiber 200 receives transmission light when an optical signal is coupled and outputs the transmitted light when the optical signal is divided or coupled out. In contrast, the second and third optical fibers 240 and 250 output transmission light when an optical signal is coupled, while they receive transmission light when the optical signal is coupled out or divided.

The optical transmission medium 210 is Y-shaped. One end of the Y shape is connected to the optical fiber 200 and the other two ends are connected to the second and third optical fibers 240 and 250 , respectively. Before preferably a residual monomer (resin) is used as an optical transmission medium. The refractive index of the optical transmission medium 210 is larger than that of the cover 220 arranged on the outside of the optical transmission medium 210 and that of the Y-shaped channel transmission path 230 . The channel transmission path 230 on which the first, second and third optical fibers 200 , 240 and 250 are formed is provided with a space to be filled with the optical transmission medium 210 . The optical transmission path 230 is formed so that it emits transmission light after the space is filled with the optical transmission medium. The cover 220 arranges the first, second and third optical fibers 200 , 240 and 250 and is arranged on the channel transmission path 230 .

Fig. 3 shows a three-dimensional view of one side of the 1 × 1 and 1 × 2 optocouplers, in which light passes through an optical transmission medium 310 through an optical fiber 300 . The optocoupler has a cover 320 and a straight or Y-shaped channel transmission path 330 . In order for the transmission light to pass through inside, the refractive index of the optical transmission medium 310 is larger than that of the cover 320 , which is arranged on the outside of the optical transmission medium 310 , and larger than that of the rectilinear or Y-shaped channel transmission path 330 .

Fig. 4 shows a three-dimensional view of one side of a 1 × 1 or 1 × 2 optocoupler, in which a fiber with a plastic jacket or a plastic fiber is arranged in front of a polymer as an optical transmission medium and light via an optical fiber 400 through a pre-hardened optical transmission medium 410 goes. The optocoupler has a cover 420 and a straight or Y-shaped channel transmission path 430 .

Fig. 5 shows a three-dimensional view of one side of an optocoupler with a U- or V-shaped groove 20 in a stepped channel transmission path 530 , which allows self-alignment of the optical fiber 500 . The optocoupler thus has a U-shaped or V-shaped groove 520 .

Preferably, the resin forming the optical transmission medium is a material with a refractive index between 1.40 and 1.60. The channel transmission paths 130 , 230 , 330 , 430 and 530 in particular each have a refractive index which is 0.02 to 0.002 smaller than that of the resin materials 110 , 210 and 310 and the polymer material 410 as an optical transmission medium, the channel transmission paths thereby are formed such that a resin is hardened from a single material or from a material mixture which can control the refractive index. The channel transmission paths 130 , 230 , 330 , 430 and 530 can each be formed via a molding process. Their cross sections can be round or rectangular, their structure can be graduated.

The covers 120 , 220 , 320 , 420 and 520 each have a refractive index which is 0.02 to 0.002 smaller than that of the resin materials 110 , 210 and 310 and the polymer material 410 as an optical transmission medium and are optical in the ultraviolet range and transparent in the range of visible light. They are formed by curing a resin consisting of a single material or a mixture of materials that can control the refractive index.

The multimode optocoupler may further include an optical connector which is not shown and which consists of a plug and an adapter connected to one end of each optical fiber 100 , 140 , 200 , 240 and 250 . The connector of the optical connector has a fiber with a plastic jacket or a plastic fiber that receives the transmitted light, an outer cover for protecting the optical fiber, a body for attaching the outer cover and a connector for connecting the connector to the adapter. The plug of the optical connector further has a device interlocking that can couple the connector.

In a multimode optocoupler, the optical fibers 100 , 140 , 200 , 240 and 250 are typically arranged on the channel transmission paths 130 , 230 , 330 , 430 and 530 . The optical transmission media 110 , 210 , 310 and 410 are arranged on the channel transmission paths. From covers 120 , 220 , 320 , 420 and 520 are provided on part of the optical fibers and the optical transmission media, whereby the manufacture of the multimode optocoupler is completed. The optical fiber can in particular be arranged firmly on the channel transmission path in that it is pressed onto the latter.

The mode of operation of the optocouplers is described below. In the 1 × 1 multimode optocoupler shown in FIG. 1, transmission light falls into the first optical fiber 100 , this light travels inside the residual mo nomer 110 , which is an optical transmission medium, with total internal reflection and the light becomes the second optical fiber 140 , which is opposite to the first optical fiber 100 .

The mode of operation of the 1 × 2 multimode optocoupler which is shown in FIG. 2 and in which a division from A to B and C and a coupling from B and C to A occur in each case are described below. In the 1 × 2 multimode optocoupler, the resin 210 is branched and merged as an optical transmission medium in the Y-shaped channel transmission path 230 through a mode field structure, the electromagnetic fields of the optical signals passing through being combined with one another.

The division of A into B and C is considered first. The light coming from A passes through the first optical fiber 200 , which consists of a fiber with a plastic jacket or a plastic fiber, the core of the optical fiber 200 passing into the cross section of the resin 210 as the optical transmission medium. The transmission light travels inside the resin 210 as an optical transmission medium, thereby dividing the optical power into equal amounts at the junction of the Y-shaped channel transmission path 230 and the divided transmission light portions falling into the second and third optical fibers 240 and 250 and then are output at B and C.

The coupling of B and C to A is considered below. The light transmitted by B and C passes through the second and third optical fibers 240 and 250 , each of which consists of a fiber made of a plastic jacket or a plastic fiber. The transmitted light then travels inside the resin 210 as an optical transmission medium and falls into the first optical fiber 200 , which is opposite to the second and third optical fibers 240 and 250 .

In the multimode optocoupler shown in FIG. 3, the transmission light falling into the first optical fiber 300 travels inside the resin 310 as the optical transmission medium and then falls into an optical fiber which is opposite to the first optical fiber 300 .

In the multimode optocoupler shown in FIG. 4, the transmission light travels inside the polymer material as 410 as an optical transmission medium under an internal total reflection and then the light falls into an opposite optical fiber. The polymer material has a structure which is different from that of the resin, the resin having a higher refractive index as the optical transmission medium because it is precured. Low loss optical transmission is possible without the influence of the residual monomer present between the cross section of the optical fiber and the wall of the channel transmission path based on the prepolymerization.

In the multimode optocoupler shown in FIG. 5, the optical fiber 500 is connected to a non-pre-cured monomer and a pre-cured monomer that are present in the stepped channel transmission path 530 and in the stepped channel transmission path 530 using the U-shaped or V-shaped groove 520 . The optical fiber can therefore self-align so that it can be easily attached to the channel transmission path 530 . The accuracy of the connection between the cores of the optical fibers is also greater, which reduces the reflection losses of the light due to an imprecise connection between the optical fiber cores.

As described above, a fiber is made with Plastic sheath or a plastic fiber related that has a larger core than typical optical night directing fiber is the case, which is contrary to  the conventional method. This is done in that the light via an optical transmission medium in one Channel transmission path is transmitted.

The influence of the resin between the cross section the optical fiber and the wall of the channel transmission path is present may be due to the core expansion after the pre curing of the resin can be eliminated. The light coupling can in this way without problems with a low-loss optical Transmission take place at the branching or coupling and connection between optical fibers at low Ko is most simplified.

The optical fibers can be made using a U or V-shaped groove will be self-aligning so that it is pro can easily advertise attached to the channel transmission path. The Accuracy of the connection between the cores of the optical Fibers is bigger, which is due to the light emission losses an inaccurate connection between the cores of the optical Fibers reduced.

Claims (18)

1. multimode optocoupler, characterized by
a first optical fiber ( 100 ) which receives transmission light and consists of a fiber with a plastic jacket or a plastic fiber,
a second optical fiber ( 140 ) which emits the transmission light and consists of a fiber with a plastic jacket or a plastic fiber,
an optical transmission medium ( 110 ) which is arranged between the first and the second optical fibers ( 100 , 140 ) and is connected to the first and to the second optical fibers ( 100 , 140 ),
a channel transmission path ( 130 ) which has a space in which the first and second optical fibers ( 100 , 140 ) are arranged and in which the optical transmission medium ( 110 ) between the first and second optical fibers ( 100 , 140 ) is filled, and which emits the transmission light after the space is filled with the optical transmission medium ( 110 ), and
a cover ( 120 ) that aligns the first and second optical fibers ( 100 , 140 ) and is disposed on the channel transmission path ( 130 ). 2. Optocoupler according to claim 1, characterized in that the optical transmission medium ( 110 ) is a residual monomer. 3. Optocoupler according to claim 2, characterized in that the optical transmission medium ( 110 ) is a resin which has a refractive index between 1.40 and 1.60. 4. Optocoupler according to claim 1, characterized in that the first and second optical fibers ( 100 , 140 ) each have a core which is larger than that of an optical communication fiber. 5. Optocoupler according to claim 1, characterized in that the channel transmission path ( 130 ) has a refractive index which is 0.02 to 0.002 smaller than that of the core expansion or extension element, and is formed in that a resin is cured, the consists of a single material or of several materials (material mixture) that can control its refractive index. 6. Optocoupler according to claim 1, characterized in that the channel transmission path ( 130 ) is formed by a molding process. 7. Optocoupler according to claim 1, characterized in that the channel transmission path ( 130 ) has a round cross section. 8. Optocoupler according to claim 1, characterized in that the channel transmission path ( 130 ) has a rectangular cross section. 9. Optocoupler according to claim 1, characterized in that the channel transmission path ( 130 ) has a stepped structure. 10. Optocoupler according to claim 1, characterized in that the cover ( 120 ) has a refractive index which is 0.02 to 0.002 smaller than that of the optical transmission medium ( 110 ), and that the cover ( 120 ) for light in ultraviolet region and in the visible region is transparent in that it is formed by hardening a resin which consists of a single material or a plurality of materials (material mixture) whose refractive index can be controlled. 11. Optocoupler according to claim 1, characterized by a U or V-shaped groove on the channel transmission path is provided so that self-alignment of it held first or second optical fibers is possible. 12. Optocoupler according to claim 1, characterized by an optical connector that is connected to one end of the first and the second optical fiber is connected and one Includes connector and an adapter. 13. Optocoupler according to claim 12, characterized in that the plug of the optical connector
a fiber with a plastic jacket or a plastic fiber that receives transmission light,
an outer cover to protect the optical fiber,
a body for attaching the outer cover and
comprises a connector for coupling to the adapter, and that the adapter of the optical connector comprises a locking device for coupling the plug. 14. A method for producing a multimode optocoupler according to claim 1, characterized in that
the optical fiber is placed in the channel transmission path,
an optical transmission medium is arranged as a core extension element on the channel transmission path and
the cover is placed on part of the optical fiber and on the optical transmission medium, wherein
the optical fiber is placed firmly under pressure on the optical transmission path. 15. Multi-mode optocoupler, characterized by
a first optical fiber ( 200 ) consisting of a fiber with a plastic jacket or a plastic fiber,
a second optical fiber ( 240 ) consisting of a fiber with a plastic jacket or an optical fiber,
a third optical fiber ( 250 ) consisting of a fiber with a plastic jacket or a plastic fiber,
an Y-shaped optical transmission medium ( 210 ) connected at one end to the first optical fiber ( 200 ) and at the other two ends to the second and third optical fibers ( 240 , 250 ),
a channel transmission path ( 230 ) having a space in which the first, second and third optical fibers ( 200 , 240 , 250 ) are arranged and into which the optical transmission medium ( 210 ) is filled, and the transmission light outputs after the space is filled with the optical transmission medium ( 210 ), and
a cover ( 220 ) which aligns the first, second and third optical fibers ( 200 , 240 , 250 ) and is arranged on the optical transmission path ( 230 ). 16. Optocoupler according to claim 15, characterized in that the optical transmission medium ( 210 ) is a residual mono mer. 17. Optocoupler according to claim 15, characterized in that the optical transmission medium ( 210 ) is a resin which has a refractive index between 1.40 and 1.60. 18. Optocoupler according to claim 15, characterized in that the optical transmission medium ( 210 ) of the Kernver extension element is a polymer material.