DE3700565A1 - Optical waveguide - Google Patents

Abstract

Published without abstract.

Description

The invention relates to an optical waveguide with a Core, a cladding and a refractive index drop in the Coat in the shape of a trench.

Recently, LED is being considered, preferably as an edge emitter can also be used in single-mode systems. The goal are cheap systems with bit rates up to 300 Mbit / s and Distances up to 10 km. Instead of an expensive gradien ten fiber with error-free refractive index profile lower Fashion dispersion is thought of as the cheaper ones in principle Single mode fibers. Monomode fibers can be cheaper because they only need a simple step profile chen. However, her coat must be at least six times the core diameter of high-purity and water free synthetic quartz glass, because otherwise the Fundamental wave with its transverse-damped cladding fields would be very subdued. In addition, the mode radius of the Fundamental wave should be as large as possible, so that one prinzi Eventually reachable and already very small incentive efficiency through an LED without sophisticated trans formation optics comes close. Despite the large fashion radius The fiber must not be too sensitive to crumbs be made.

The invention has for its object a light waveguide with large mode radius, with low dis persion and to indicate with low damping, except which is inexpensive to manufacture. This task will in an optical fiber of the type mentioned solved according to the invention in that the trench is not borders directly on the core, but at a distance from Core is arranged inside the jacket.

According to the invention is a generally ringför cross-sectional area with reduced refractive index con centric to the fiber core, which is not immediate borders on the core, but at a distance from the core in Inside the coat.

The invention is based on an embodiment example explained.

Fig. 1 shows the refractive index profile of a three-stage fiber according to the invention. Their homogeneous core of the refractive index n _k and the diameter 2 a is surrounded by an inner jacket of the refractive index n _m up to the diameter 2 b. A second cladding has a refractive index reduced to n _t and the outer diameter 2 c. The outer cladding again has the refractive index n _{m of} the inner cladding.

This fiber can be produced cheaply by using the MCVD process to coat a substrate tube made of ordinary and therefore lossy quartz glass first with, for example, boron or fluorine-doped quartz glass, so that the refractive index is reduced to n _t , then one or a few layers of pure quartz glass with a refractive index n _m and finally quartz glass with a refractive index n _k in one or a few layers for the core, which is doped with germanium, for example.

The refractive index valley (refractive index index ditch), the example is fluorine or boron doped, increases the transverse damper tion of the fundamental wave fields, so that they are not in the outer coat is enough. This will even with one relatively thin inner coat made from just one or whole few MCVD layers through the fundamental wave attenuation Absorption and scattering in the outer coat low In addition, due to the radial limitation of the Fundamental wave fields due to this transverse attenuation in the refractive index tal the fiber relatively insensitive to Be curvatures. When you are making a Optical fiber according to the invention as described above starts from a substrate tube, so prevents breaking pays out that impurities, mainly OH ions the substrate glass in the inner coat. To calculate this three-stage fiber so that it can be produced as cheaply as possible, and at a large mode radius is not very sensitive to curvature, and around the limit of their transmission capacity through the Determining fundamental wave dispersion is preferred of only small differences in refractive index in the profile out. One can then use the scalar approximation for the Solution of the vector wave equation for the fiber fundamental wave and for the next higher eigen waves and for the calculate those radiation waves which occur with fiber crumb in the outer jacket stimulated by the fundamental wave will.

LEDs have an emission spectrum up to 100 nm wide. If with them 300 Mbit / s over a fiber length of up to 10 km the dispersion coefficient must be transferred according to the equation

remain less than 3 ps / (nm · km). N 'is the group index, c is the speed of vacuum and g is the wavelength. So little linear fundamental wave dispersion requires an operating wavelength near a zero of the dispersion coefficient. The material dispersion of pure quartz glass has this zero at λ = 1.28 µm. Gerium doping shifts this dispersion minimum only slightly to longer waves. With the desired large mode radius, the numerical aperture of the fiber can only be small and therefore the waveguide dispersion of the fundamental wave can only be weak. Therefore, it also shifts the dispersion minimum only slightly to longer shafts. Only operating wavelengths around λ = 1.3 µm can be used if signals are to be transmitted with low dispersion using LED radiation. With laser radiation, the fiber according to the invention can also transmit signals with low dispersion and low loss at other wavelengths.

With a relative increase in refractive index

of the core of only Δ _k = 0.3%, about 2 a = 8 µm core diameter are required in order to keep the fiber single-wave at λ = 1.3 µm. With such a small Δ _k , the increase in damping due to germanium doping remains within limits and, with the associated large core diameter, the mode radius is also large.

The width of the refractive index valley increases

c - b = 1.6 µm

limited so that it only requires one or a few layers in the MCVD process. For a corresponding reason, the radius ratio of the inner cladding and the core is initially selected to be only b / a = 3. Lower the relative refractive index

between r = b and r = c can be easily adjusted to about Δ _t = 0.3% with fluorine doping.

Fig. 2a shows the dispersion coefficient according to the above dispersion coefficient equation as a function of wavelength for three different three-stage fibers which have been sized according to these considerations. The specified refractive index differences apply to λ = 1.3 μm, but change only slightly due to the Sellmeier equations in the relatively narrow spectral range of FIG. 2b. The fibers 1 and 2 have theoretical limit wavelengths λ _c for their single-wave properties below the dispersion minimum. In the case of fiber 3 , this limiting wavelength is above the minimum dispersion; however, the fiber 3 is still effectively single-wave in the dispersion minimum, because the next higher wave extends far into the outer jacket and it drives a correspondingly strong jacket damping. The effective mode radius for all three fibers and waves is longer than 1.25 µm over 4.5 µm, which can be considered sufficiently large.

The fundamental wave attenuation due to losses in the outer jacket can be specified in relation to the volume damping α _m in the outer jacket. If this volume attenuation is, for example, α _m = 100 dB / km, this results in a fundamental wave attenuation of Δα = 0.0086 db / km for fiber 2 at λ = 1.36 µm. Otherwise, this fundamental wave attenuation is always much lower in the examples of FIG. 2, because of the then smaller mode radius.

The depth and radial position of the refractive index trench is decisive for this fundamental wave attenuation due to losses in the outer cladding. The design examples in Fig. 2 show that at b / a = 3 and Δ _t = 0.32% the fundamental wave attenuation due to losses in the outer jacket is still far lower than the normal fiber attenuation at λ = 1.3 µm of α = 0, 4th . . 0.8 dB / km remains. So you could still save on inner cladding layers and get by with a smaller b / a . For this purpose is shown in FIG 3, this fundamental wave attenuation Δα relatively to the losses in the outer shell as a function of b / a for values of a, c -. Δ _k corresponding to b, the other requirements for this three-stage fibers. It can be seen that in this example and for external jacket losses of α _m = 100 dB / km, the additional fundamental wave attenuation remains less than 0.1 dB / km for b / a <2.

Alternatively, in order to further simplify preform production using the MCVD process, one can get by with less lowering of the refractive index in the middle cladding, ie doping the quartz glass with less fluorine or with boron instead of fluorine. For this, the Fig. 4, as the increase Δα shows the fundamental wave attenuation relative to the losses α _m in the outer shell of the relative refractive index lowering in the middle coat depends. In order to obtain a cheaper fiber, the inner diameter of the middle jacket was reduced to b / a = 2.2 compared to FIG. 2, but the other parameters were chosen as in FIG. 3. With the refractive index lowering of the middle coat can be determined by the Fig. 4 may not change the additional fundamental wave attenuation as dramatic as with the radial position of this refractive index valley, but Δα = 0.1 dB / km at a _m = 100 dB / km range here already 0.13% relative reduction in refractive index.

Finally, it should also be investigated how sensitive the three-stage fiber with lowering of the refractive index in the middle cladding is to curvature. For this purpose, the average microcurvature losses ( α ) were calculated with a spectrum of curvature as in the equation Φ ( Ω ) = K / Ω ^{2 p} with

K = 9.68.10 ^-19 (dB / km) µm ^-2p and p = 3.2

With these parameter values for the curvature statistics the same results for simple step fibers Microbending losses also as a function of wavelength, as they are practical for these fibers conditions are measured. That's why you can also for Three-stage fiber with refractive index valley with these parameter values calculate for the curvature statistics.

As a result, Figure 5 shows the FIG. Microbending losses as a function of the radius ratio b / a. ( α ) increases monotonically with b / a , but already asymptomically approaches the value that applies to the corresponding step fiber without refractive index valley for b / a <3.5. Even this limit is only ( α ) = 3.10 ^-4 dB / km, which is far below the 0.03 dB / km that could be practically tolerated.

Fig. 6 shows the bending losses as a function of the relative refractive index reduction in Brechzahltal at b / a = 2.2, that is a radial distance of the refractive index of the valley from the core, with the fundamental wave attenuation is held by losses in the outer shell still sufficiently low. In line with the FIG. 5 (α) increases for Δ _t = 0 to 3 x 10 ^-4 / km dB, but is otherwise always lower. All in all, the three-stage fiber with refractive index tolerates normal microbends without the fundamental wave attenuation noticeably increasing. Even if the refractive index valley is shifted radially or its refractive index reduction is changed, the fiber remains insensitive to microbends.

In order to have to deposit only a few MCVD cladding layers for a cheap monomode fiber with a large mode radius and little attenuation and dispersion at λ = 1.3 µm, the basic wave attenuation due to losses in the outer cladding can be done with a fluorine or boron-doped refractive index between the inner cladding and the substrate glass be kept small enough. With a core diameter of about 8 µm, the inner jacket only needs to be about 4 µm thick. The refractive index valley only needs a width of 1.6 µm and about 0.2% relative refractive index reduction. Even 100 dB / km losses in the outer jacket only increase the fundamental wave attenuation by less than 0.1 dB / km. The fundamental wave, with its then about 5 µm mode radius, remains insensitive to microbends.

Claims (6)

1. Optical waveguide with a core, a jacket and with a lowering of the refractive index in the jacket in the form of a trench, characterized in that the trench does not directly adjoin the core, but is arranged at a distance from the core in the interior of the jacket. 2. Optical waveguide according to claim 1, characterized shows that the trench is at such a distance from the Core is provided that on the one hand for the coat in Area between core and trench as little mate as possible rial is required and on the other hand the influence of Loss of material outside the trench and from micro curvatures on the fiber attenuation is minimal. 3. Optical waveguide according to claim 1 or 2, characterized in that the ratio of the inner radius b of the trench to the core radius a is chosen such that 1 < b / a <5. 4. Optical waveguide according to claim 3, characterized in that the ratio of the inner radius b of the Gra ben to the core radius a is chosen such that 1.3 < b / a <3. 5. Optical waveguide according to one of claims 1 to 4, characterized in that the width g of the trench is chosen such that 0.2 < g / a <1, where a is the core radius. 6. Optical fiber according to claim 5, characterized in that the width g of the trench is selected such that 0.3 < g / a <0.6.