DE4335428A1 - Optical frequency splitter using Bragg diffraction directional couplers - Google Patents

Abstract

The zero-dB fused optical fibre coupler comprises two fibres (1,2) with their cores (4) and GeO2-doped sheaths (5) combined over the coupling region (6), in the centre of which a Bragg grating (3) of relatively short length is produced by photo-refractive effect. The radial distribution of dopant in the fibre sheaths may allow for the different field distribution of LP01 and LP11 waves so that the effective variation of refractive index is the same for both modes, and polarisation dependence is reduced.

Description

The invention relates to an optical crossover with high Selectivity for optical communications technology.

It is known that waveguide couplers are selective by themselves Have properties, because with a suitable coupling length the Energy oscillates between the two waveguides depending on the frequency. By appropriate dimensioning it is achieved that for a Wavelength full forward crosstalk (0 dB coupling) and for the other there is no forward crosstalk.

Such crossovers have the disadvantage that they are only for certain areas of application are suitable, since only small Selectivity is achieved, the relative minimum bandwidths a few percent, and especially periodic behavior is present.

Furthermore, an embodiment is known, which in principle the Requires a highly selective crossover. she consists of two 3 dB couplers, the two rear gates of the first coupler with the two front gates of the second Couplers are connected and a Bragg grating in each Connection lines between the couplers is provided. in the Reflection band of the grating becomes the first coupler twice run through, so that the two 3 dB couplings to 0 dB add and full reverse crosstalk occurs. Outside of Reflection band, both couplers act together as a 0 dB coupler, see above that full forward crosstalk results.

Disadvantages of this solution are the requirement for exact equality the optical path length on both connections between the first Coupler and the grilles, between the grilles and the second Coupler and in the grilles themselves. These parities on small Fractions of an optical wavelength are very technological difficult to realize.  

Unsymmetrical fiber couplers with a grating are also known in one of the fibers with the lattice constant Λ and the Effective refractive indices n₁ and n₂ of the two fibers. Coupling through the Grating occurs when A is equal to the beat wavelength of the coupling modes. Therefore, reflection results in one of the Fibers at the wavelengths

λ _R1 = ²n₁Λ and λ _R2 = ²n₂Λ (1)

and the desired reverse crosstalk

λ _E = (n₁ + n₂) Λ (2).

The asymmetry is used for backward crosstalk and reflection to separate in frequency. Forward transmission also takes place in each fiber and the forward crosstalk common to fiber couplers.

The disadvantage of this coupler is that it behaves in many ways Is away from an ideal crossover because especially due to the asymmetry, neither complete Forward or backward crosstalk is achieved.

The object of the invention is to be technologically simpler realizing crossover, the full benefits of the Bragg grating to bring effect.

According to the invention the object is achieved in that in one known directional couplers in the range of the coupling length of the Waveguide is generated at least one Bragg grating.

By relocating the Bragg grating to the area of Coupling length of the waveguide, will manufacture the Crossover technologically controllable, and the advantageous Effect of the Bragg grating, reflections with a narrow bandwidth, can be fully effective. The reflected part  the power is preferably at the non-powered input of the Coupler available for further processing.

By selecting the lattice constants and lattice length accordingly generation of the Bragg grating, reflections can be certain Wavelength and bandwidth are generated and accepted. Conceivable is also the cascade-like interconnection of n crossovers according to the invention to a larger number of to provide narrowband carrier frequencies. Of the The advantage is that due to the small bandwidth many Channels per nanometer wavelength can be provided.

Condition for an ideal crossover of the type according to the invention is that the relative difference in phase coefficients from and push-pull shaft of the directional coupler is small compared to that relative bandwidth of grating reflection.

In addition, the directional coupler should be at least functionally symmetrical his.

In the important embodiment in claim 2, the Input spectrum reflected a narrow band. The frequency will determined by the lattice constant. With longer grid lengths to take into account the position of the center of reflection and a Use arrangement according to claim 3.

If broader bands or several individual frequencies are to be reflected by a correspondingly dimensioned grating, the grating length becomes long. Since the locations of the 3 dB coupling are also wavelength-dependent, an arrangement according to claim 4 is to be provided. In addition, the total length of the coupler can be selected such that full crosstalk, namely for (β _even -β _odd ) · 1 = (n + 1/2) π, or no crosstalk for (β _even -β _odd ) for the frequencies that are not reflected ) · 1 = nπ occurs or that the power is divided in a certain ratio.

When using fiber fusion couplers is essentially only a common waveguide and thus a common grating. Since the cores become almost ineffective, the light is guided in the main thing is through the jacket material. With photorefractive Generation of the lattice is the use of fibers, too the sheaths or partial cross-sections of the same GeO₂-doped or are coded, an advantage. Another variant is generation of the grid on the surface of the jacket by etching grooves around the Coat around.

If fiber loop couplers are used, they remain Optical fiber cores are essentially effective. Here's where photorefractive path generated lattice in the by coupling closely adjacent optical fibers, preferably together manufactured. Single insertion into the coupling halves is possible. Since the light conduction essentially through the core done, is only the usual fiber with GeO₂ doping of the core required.

If the generated grid is not in the place of optimal optical path length, its location is photorefractive Readjusted paths according to claim 8. The adjustment is made by Irradiation of individual fiber cores with focused unstructured UV light.

The advantage of the solution according to the invention is that Simply produce crossovers of the type described and are characterized by a high selective effect.

The invention is explained in more detail below using an example. In the drawing shows

Fig. 1 shows a 0 dB fiber fusion coupler with Bragg grating

In Fig. 1, a fiber fusion coupler is shown. The fibers 1 and 2 with their cores 4 and shells 5 are fused together in the coupling area 6 , greatly stretched and thus tapered. The fiber cores, which are responsible for guiding the light outside the coupling area, are hardly effective in the central area. The light is guided more strongly through the waveguide formed by the cladding material. The model of the superimposition of common and push-pull wave was used for the analysis. They correspond to the LP₀₁ or LP₁₁ wave in the middle. According to the invention, the coupler is provided with the Bragg grating in the middle of the coupling length of the waveguide. The grid is generated photorefractive. Since the photorefractive effect can currently only be achieved with germanium dioxide doping, fibers with a GeO₂-doped cladding are to be used. The radius dependence of the doping can take into account the different field distribution of LP₀₁ and LP₁₁ in such a way that the effective change in refractive index is the same for both modes and, moreover, the polarization dependence is reduced.

Is z. B. the effective, ie weighted average, respective refractive index change in the grating Δn = 10 ^-4 - 10 ^-3 , then about 3 · 10lex - 3 · 10³ grating periods with half the fiber wavelength are required for a maximum total reflection of about 1 for simple grating. This results in grating lengths of 15-1.5 mm and bandwidths of approximately 30-300 GHz in the 1.55 µm band.

Claims (8)

1. Optical crossover, consisting of directional couplers using Bragg gratings, characterized in that at least one Bragg grating is provided in the area of the coupling length of the waveguides of a directional coupler. 2. Optical crossover according to claim 1, characterized in that the directional coupler is a 0 dB coupler, the Lattice length is small compared to the coupling length and the lattice is arranged in the middle of the coupling length of the waveguide. 3. Optical crossover according to claim 1, characterized in that the directional coupler is a 0 dB coupler, the grating is arranged off-center and the focus of the Grating reflection in the middle of the coupling length of the waveguide lies. 4. Optical crossover according to claim 1, characterized in that the directional coupler has a 0 dB coupler Multiple coupling is and multiple grids with different lattice constants are provided. 5. Optical crossover according to claim 4, characterized in that the grids are arranged at the points those for the grating reflection frequency the 3 dB coupling is achieved. 6. Optical crossover according to claim 4 or 5, characterized in that the total length of the coupler is chosen so that for those not to be influenced by the bars frequencies of interest full or none Forward crosstalk occurs.   7. Optical crossover according to claim 1, 2, 3, 4, 5 or 6, characterized in that the lattice constant of Bragg grid along a mathematical connection the coupling length changes. 8. Optical crossover according to claim 1, 2, 3, 4, 5, 6 or 7, characterized in that the optical path length of the fibers individually adjusted photorefractive.