SE514479C2 - Process for producing a fused optical fiber coupler and the fiber coupler as such - Google Patents

Abstract

A fused optical fiber coupler comprises as conventional two or more optical fibers (1) fused to each other and thinned within a short segment. The fibers used have an extra doping of especially selected atoms such as nitrogen in the cores (11). When heating the segments to fusion them to each other, these extra dopant atoms have diffused out of the original core regions and have even been eliminated from the fibers reducing the refractive index of the cores. New cores are formed enclosing the former core regions, making the cores within the heated segments also wider. When pulling the fibers within the heated segments for thinning them these new cores are also being thinned. The redistribution of dopants changes the refractive index profile so that the modefields of light propagating in the segments will be wider than without any diffusion or releasing of dopant. The wider modefields give wider evanescent fields in the fused segments making light interact more easily in the segments, resulting in that the heated segments must not be drawn to such a large extent or to be as thin or narrow as conventional. This gives fused segments considerably thicker than the fused segments of a conventional fused coupler. Such an optical coupler can be more easily handled and is less subjected to breaks or ruptures. In particular, the optical coupler will have a greater fracture load, longer lifetime and a better temperature stability than conventional fused couplers.

Description

5 20 479 2 next to each other, and then heating the portions or parts thereof to melting temperature, so that the fibers adhere to each other, while the holders are moved at the same time, so that a tensile force or stretching force is exerted on the parts of the fibers which held between the holders. During the drawing step, the heated portions of the two fibers become thinner, which has the consequence that the cores of the two fibers also become thinner and that the cores are also located closer to each other.

The refractive index profiles of the two fibers are also deformed. Then the optical effect in a ground node for light propagating along one of the fibers will be divided between the two fibers in the fused portion, thereby causing the light wave to be divided in the fused area to be propagated along both brims. The high melting temperature of typically about 1800 ° C can be obtained from a flame, an electric arc, a laser light beam, heat from light rays concentrated by lens systems, or from an oven comprising electric resistance heating elements or similar equipment, etc.

The division of optical power in the fused portion is called optical coupling and can be explained by a partial overlap of the evanescent part of the mode field of light, which propagates along the two optical beams. The coupling relationship between the power of the light wave propagating in the incarnating nucleus and the power of the light wave propagating along the other nucleus depends on the overlap between the mode fields, ie on the mutual distance between the cutting lines through the nuclei of the two to some extent also on the length of the coupling portion or the fused portion. The coupling ratio can be set to 50/50 or 70/30, 10/90, 1/99, etc. by designing the fused portion in a doctrinal manner.

In general, such a coupler comprising two fused fibers has four ends and is thus a 2x2 coupler and furthermore it is symmetrical in the longitudinal directions of the coupler, i.e. it has the same coupling conditions and transmission properties for light waves which enter in both directions. This type of fused coupler is typically useful, i.e. has good overdrive properties such as low losses, very high signal bandwidth, within a wide wavelength range such as in a range comprising 1270 - 1340 nm and / or 1520 - 1570 nm.

Fused couplers made of single modes further have low polarization dependent losses except in the case of low coupling conditions such as below 10/90. In addition, provided they have been given appropriate mechanical protection, they are reliable in various applications, such as not being sensitive to temperature changes or humidity. p When one of the two burners is cut off in a place near the fused part, so that it does not reflect light waves, the 2x2 coupler becomes a 1x2 coupler. Furthermore, a similar method can be used to make 3x3 and from it 1x3 or 2x3 couplers by using three optical fibers, which are drawn and fused together at the same time, or even NxN couplers (or 1xN, 2xN -, etc.) can be manufactured. A common feature of the optical fiber couplers is that the optical power is coupled from an input carrier, which may be any of the cables, to each of the cables on the opposite side of the coupling portion, the coupling portion being indicated by "xzet". in the terms 2x2-, lx2- etc. 5 10 15 DISCLOSURE OF THE INVENTION It is one of the present invention to provide an optical fiber coupler with good temperature stability.

It is a further object of the present invention to provide an optical coupler with good mechanical strength, which allows it to be handled without any risk of breaking it and which thereby has a long service life.

Thus, in a fused optical fiber quartz coupler, similar optical fibers of standard type are used, see ITU G.651, G.652, G.653, G.654, G.655, etc., as starting material. At least one of the optical fibers used contains a specially selected dopant material.

In particular, only the core of only one of the optical fibers used may contain the specially selected dopant, which may be N (nitrogen). The cores may normally also contain standard doping materials such as Ge, B, etc., all doping materials being added to make the core refractive index greater than the refractive index of the surrounding shell material, which thus has a lower refractive index and may be substantially undoped. In a fusing work step in the production of the fused opp coupler, the special dopant distributes itself within the area heated during the fusing work step. The redistribution causes a change in the refractive index in the area, which leads to a reduced absolute difference between the refractive index of the core area and the area that surrounds it. In particular, the particular dopant, such as N atoms / molecules, in the nucleus of one of the optical fi brems may partially diffuse zu out to the surrounding fi mantle, so that the diffusion gives rise to a decrease in the refractive index of the nucleus and an insignificant increase in refractive index in a layer around the core, which for example leads to a widening of the cores or at least a reduction of the refractive index of the cores. In the fusion step, at the same time, the cores of all the fused fibers are made narrower due to the elongation of the fibers.

The reduction of the refractive index difference or generally the change of the refractive index in turn leads to a widening of the mode field of the fundamental modes or the guided modes in the said optical waveguide considered as optical waveguide, the widening being compared with the width of the mode fields of an optical beam. has the same original refractive index profile seen in cross section and which is expressed in the same way but in which no redistribution of dopants has occurred during the heating process and thus the refractive index profile is uniform with the profile of the original ñber, ie in which the refractive index difference uniform reduction of the original protein.

The particular dopant is chosen so that its redistribution, in particular a diffusion thereof, preferably occurs only at a very high temperature, close to the melting point of the optical fibers. With a doping with nitrogen, this diffusion begins to occur at about 1500 ° C and is effective at temperatures around and above 1800 ° C, ie during the heating process, when the two fibers are fused to each other.

The particular dopant would also have originally been added only to the jacket of an optical fiber, the particular dopant during the heating process also diffusing into the core and reducing its refractive index. More complex doping schemes can also be obtained by combining special dopants in both the core and the mantle of the optical beam, the dopants possibly also reacting chemically in the heating process and changing the refractive index in the desired way, so that the mode fields are widened.

The swelling of the cores, i.e. the increase of the effective diameters of the cores, by the diffusion during the fusion step leads to the fact that it is not necessary to draw fi brema to the very narrow diameters, such as 30 to 50 μm, which are used in the prior art. Depending on the effect of widening the mode field, especially the core or cores, the final thickness of the thinnest portion of the coupler may be at least 20 - 50% thicker than in similar optical fi couplers made without any widening of the mode field such as swelling of the core in single mode , and even in multimode bers, a certain increase in the thickness of the bead portions inside the coupler can be obtained compared with conventionally made fused bead couplers. The increased diaphragms give the fused couplers an increased strength in the coupling portion. Thus, the strength, i.e. the breaking stress at the weakest crack, of the bare coupler is thus at least about 40% higher than for standard couplers made of optical fibers without any significant change of refractive index in the heating process, such as diffusion-based swelling of the cores, provided they have the same weakest cracks. sizes.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described as a non-limiting exemplary embodiment with reference to the accompanying drawings, in which: Figs. 1 and 2 are schematic views showing the manufacture of a fused optical fiber coupler by means of a flame and an electric arc, respectively. a combined fusing and drawing step, Fig. 3 is a schematic view of a fused optical coupler, Figs. 4a, 4b, and 4c are diagrams showing the refractive index profile and concentration profile of Ge and N, respectively, in a step index type optical carrier, which is used in the manufacture of an optical fiber coupler, - Figs. Sa, 5b and 5c are diagrams of the refractive index profile and concentration profile of Ge and N, respectively, of a heated portion of the optical fiber, which have those in fi g. 4a - 4c show the probes, and - Figs. 6a, 6b and 6c are diagrams of the refractive index profile and concentration profile of Ge and N, respectively, in an optical fiber of the type having them in fi g. 4a - 4c show the probes, after a heating and drawing work step, which is used in the manufacture of an optical fiber coupler.

DESCRIPTION OF THE PREFERRED EMBODIMENT I fi g. 1 and 2 illustrate the production of a fused optical coupler. Thus placed as seen in fi g. In two optical beams 1 in contact with each other and in parallel with each other over a suitable length, the fibers being held by holding devices, not shown. 10 15 20 25 30 35 _ M _ _ _,.,, -_.

I. . _ - '<' '". - = lufj' 1 fc: f .l e. ifkv,, _ _ .. ice = i: ff-. 1 f. - -> f: ~ ^ f ~ f NM Pâ en place or in an area within this length, the two fibers are heated intensively by means of a flame 3 from a microburner 5. The flame 3 heats an area of the two fi burners 1 to a very high temperature of the order of eg 1800 ° C to get the för burners to melt or at least be half-melted.The flame can be flattened laterally to make the heated area longer.At the same time, the two fi brers 1 are subjected to a tensile or tensile force as indicated by the arrows 6. Then the heated portions of the two fi brema together, so that the sheaths of the fi bricks adhere to and melt into each other and form a single part or a single fused portion depending on the surface tension and at the same time they become thinner in the heated area due to the tensile force. The heat can for instance also be obtained from an electric arc 7, which is generated between electrodes 9 s as shown in fi g. 2.

In the heated portion, the cores 11 of the two members 1 will be placed closer to each other due to the simultaneous pulling and also a taper of the cores will normally be obtained within the heated portion. Of course, the refractive index of the batches of the two inoms within the heated part can also be changed by the heating process and thereby the propagation properties of light propagated in the fibers, this effect being derived, for example, from diffusion of dopant atoms or of chemical changes. The finished coupler is shown in fi g. 3.

However, the two optical brakes 1 used in the assembly and pulling process are the same as! a standard single-mode ice-fiber or multimode fiber according to ITU 6,651, 6,652, 6,653, 6,654, 6,655, etc., but they have been given an additional doping of a specially selected material, here preferably nitrogen (N), in their cores. Typically, the cores have a sheath of silica glass, which normally has an outer diameter of 125 μm, and the cores 11 typically have a diameter of 5 - 10 μm for single optical optical fibers or a diameter of about 50 - 62.5 μm for optical multimodñbrer. The fibers can in the usual way be coated with a double layer of a primary polyacrylate coating of a standard type with, for example, an outer diameter of 240 - 250 μm and on top of this a thin color layer with an outer diameter of 250 μm, which can also be the diameter of the optical fibers. taken together with their protective coating.

During production, such coated ñbres are then peeled or they are freed from their protective coatings over portions with, for example, a length of approximately 20 mm. The two brakes are then mounted in some fusing and transport / traction device, here symbolically indicated by the micro-sensor 5 and the electrodes 9, respectively, as described above. The fibers are held at the ends of the nalma portions of holders or clamps, not shown, and an alignment device, not shown, guides the portions between the clamps so that the center portions of the bare portions of the two optical fibers are placed adjacent to and in contact with each other. The heating source 5 and 9, respectively, are located at a suitable place within the section portions at some distance from the alignment device. Then the heating is started and heat is applied in the adjacent middle portions and the bare parts, as shown in fi g. l and 2. At the same time apply a 10 15 20 25 30 35 U-.i * (I, _. - | riy.,. »_,.«.. _ f Qr 11-. <inf »(t- '' CL '... «. I. Si.......... Tensile or tensile force on the bare portions by moving the clamps in a corresponding manner. The heated place of the kans can be moved some distance over the the portions are placed next to each other by moving the clamps and / or the heating source and then the alignment device is also moved in a corresponding manner, while the drawing of the fibers is continued.The heating, feeding of the heated place and the drawing are continued, until a fused connecting portion with a desired The temperature of the heated parts can be estimated to be somewhere in the range 1500 - 2000 ° C. After heating the 1 members 1, which are now fused together within the parts, the cooling part and the coupler and the coupler are allowed to cool. are finished.

Finally, a protective sleeve or similar protective element can be applied around the bare portions of the two optical fibers to protect the rather sensitive bare fiber surfaces.

The length of the bare portions after the fusion and drawing work step is about 25 - 70 mm.

As shown in the article by V.I. Karpov, M.V. Grekov, E.M. Diariov, K.M. Golant, R.R. Klirapko, "Ultra-thermostable long period gratings written in nitrogen-doped silica bers", Mat. Res. Assoc. Symp. Proc. vol. 531, 1998, it turns out that at elevated temperatures, above 1500 ° C, nitrogen atoms diffuse quite easily into silica material. Germanium atoms, which are normally used in the cores of optical fibers to give them an increased refractive index, do not diffuse as easily and not even to any appreciable degree at temperatures below 2000 ° C.

However, for temperatures around or above 2000 ° C, a noticeable diffusion of Ge atoms can be found, especially if the heating is continued for some time, this effect being used in a conventional manner in expansion of the cores, when optical fibers are spliced with other optical fibers which have different core diameters, or when optical cables are to be connected to special devices.

I fi g. 4a, 4b and 4c show the refractive index and dopant concentrations in the fibers 1 before heating. For the sake of simplicity, the fibers are assumed here to be step index fibers, as shown by the diagram in fi g. 4a. In the nucleus there is then a fairly uniform concentration of Ge and N atoms. After the fibers have been subjected to a heating process, which is applied in the manufacture of an optical opp carrier coupler as described above but without any drawing of fi brema, the refractive index and concentration problems will look as shown in the diagram in fi g. 5a, 5b and 5c. The nucleus then becomes wider, as seen in the diagram in Fig. 5a.

The main effect is diffusion of N atoms, as seen in fi g. 5c. After the heating process, the N atoms will occupy an area which has a significantly larger diameter than the diameter of the nucleus before the heating. The effect of the heating process on the content of Ge atoms will hardly be noticeable, as seen in Fig. 5b. When the drawing of the fibers during the fusion is also taken into account, the diagrams in fi g are obtained. 6a, 6b and 6c. Thus, the special optical fibers have obtained a reduced diameter, for example a reduction of about 5 - 20%.

At the same time, the diameters of the respective area inside the optical fibers are reduced, so that the cores after the drawing work step can, for example, have a diameter approximately equal to the core diameter. ..f .. '1 §; ', _' .Z (. I cr çfgf, _ ~ '.: I “få t I. <1- v °° * meter of the original optical fibers, as seen in fi g. 6a.

The relative concentrations of N and Ge atoms in the nucleus are chosen to give the finished coupler the desired core diameter, taking into account the properties of refractive index increase that these two atomic species have.

By using an additional dopant which gives an increase in the refractive index or the optical density and is located in the core and which has such diffusion properties that it diffuses to a considerable extent during the heating step, when the fibers are heated to form the fused portion, which forms itself coupler, the optical brakes need to be pulled to a lesser extent than when fused optical couplers are manufactured in a conventional manner from standard brakes. This in turn means that the finished coupler has a larger diameter overall and therefore has a greater mechanical strength such as a 40 - 200% greater strength for a single-node type optical coupler. In addition, the drawing work step will not be as sensitive to mistakes, since the fi brema is not pulled out to such small diameters, and in addition the life of the fiber optic couplers described here will increase, especially during tensile stresses and in difficult environments. The fiber optic couplers are also very stable, since the diffusion of N atoms only takes place at temperatures around or above 1800 ° C, which results in couplers which have very good stability under temperatures of, say, at least 100 ° C.

The very good transmission characteristics including a large wavelength range and extremely large bandwidth, low PDL and very good temperature stability are the same as or better than for standard type fused fiber couplers. The switches described here are specially designed for "fiber-to-the-home" type applications and local area network applications, for WDM and DWDM systems and devices, and for ñber-amplifier optical devices. The couplers can be easily spliced using standard fusion methods to any other single mode or multimode fiber or connected to any type of single mode or multimode connector or any other type of connector with any other fiber and with any fiber. other device or O / EE / O arislutriation.

Claims (10)

10 15 20 25 30 35 ä, _. _. _ »(I l | v 1 '' l i,; v, f: .-., ,,,. .-. 4 9 (Åk (J, (e. Ä,,, .. _. T PATENTKRAV A method of manufacturing a fused optical fiber coupler, the method comprising the steps of: - providing at least two optical fibers, each having a core and a sheath surrounding the core, - placing the optical fibers in contact with and in parallel with each other along a portion, - to heat an area within the portion to a fusing temperature, so that the optical fibers are fused or semi-fused within the area and fused together with each other within the area and at the same time pull out or subject the optical brakes to tensile stress, so that the optical fibers are stretched within the range and become narrower within the range, characterized in that in the step of providing the at least two optical fibers, at least one of the at least two optical fibers is doped with at least one dopant to give the core an original refractive index profile, wherein at least one of the at least one dopant is selected, so that in the heating step at the fusion temperature the said at least one dopant the substance is repositioned and changes the refractive index and gives the optical fiber an altered refractive index profile within a part of the area to make modal, belonging to light, which propagates in the said at least one of the at least two optical fibers, wider within the area than within an area of an optical fiber which originally has the same original refractive index profile and which is diluted and extended in the same way, but in which no dopant significantly differentiates in the heating step and / or changes refractive index in the range to reduce the difference between core refractive index and mantle refractive index. 2. A method according to claim 1, characterized in that in the step of providing the at least two optical fibers, said one of the at least two optical fibers is doped with at least one of the at least one dopant 'in the core of the optical fiber. fi bern, so that in the heating step at the fusion temperature the said one of the at least one dopant diffuses out of the core and thereby changes the refractive index and gives the optical fi bem an altered refractive index profile. A method according to claim 2, characterized in that in the step of providing the at least two optical fibers, in the diffusion of said at least one of the at least one dopant, a widened core is formed in the area, the widened core having a diameter larger than the diameter of a core within a range of an optical carrier, which originally has the same original refractive index profile and which is heated and extracted in the same manner but in which no dopant significantly differs during the heating step. 4. A method according to claim 2, characterized in that in the step of providing the at least two optical fibers, the at least one of the at least one dopant is selected to comprise nitrogen atoms. Method according to claim 2, characterized in that in the step of providing the at least two optical fibers, said at least one of the at least two optical fibers is provided with a core, which also has a doping of a material, which does not contain nitrogen <\ 10 15 20 25 30 35 f; __.: - t: -. «_ f ~ << f * ii '~,: i: t ï I.. .ir '. , ".i t« <r c: ï “í ~ *. ~“ t. » t L. .N - .I X '' f (f 'and which increases the refractive index i 6. A method according to claim 2, characterized in that the step of providing the at least two optical beams, said at least one of the at least two optical beams is provided with a core, which also has a doping of at least one material. selected from Ge and B. A fused optical coupler comprising: - at least two optical fibers, each of the at least two optical fibers having a core having a doping and a sheath surrounding - an area of the at least two optical fibers, in which the sheaths of the optical fibers two optical fibers are fused together and in which the sheaths have a diameter smaller than the diameters of the at least two optical fibers outside the range, characterized in that at least one of the at least two optical fibers having an original refractive index profile contains doping atoms, which are capable of being redistributed at temperatures used in a heating process, when the coupler is being manufactured, and during the period of time used for the heating, the redistribution being such that a substantial redistribution of doping atoms takes place and changes the refractive index and gives it the optical fiber an altered refractive index profile within a part of the range to make mode fields of light, which is propagated in the said one of the at least two op fi brerria, wider in the range than in the range of an optical fiber, which originally has the same original refractive index profile and which is heated and drawn in the same way but in which no dopant diffuses significantly during the heating step and / or that change the refractive index within the range to reduce the difference between the refractive index of the core and the refractive index of the shell. Fused optical coupler according to claim 7, characterized in that the core of said at least one of the at least two optical fibers contains doping atoms capable of diffusing at temperatures used in the heating process, when the coupler is being made, and during the time period, which is used for the heating, the diffusion properties being such that a significant diffusion of the dop atoms takes place and changes the refractive index within the range. Fused optical coupler according to claim 7, characterized in that the dopatomeria is capable of diffusing to a considerable extent at a temperature in the range 1500 - 2000 ° C, preferably at temperatures of substantially 1800 ° C. Fused optical coupler according to claim 7, characterized in that the dop atoms comprise nitrogen, which in the region form deformed nuclei, in which the nitrogen atoms have diffused out from the original nucleus, the nitrogen atoms being in a diffused state and forming a new nucleus. , which surrounds the original core of the area.