DE4216922A1 - Reflected energy attenuator for optical communication system - is based on ion implantation of section of fibre between two standard monomode sections with less attenuation - Google Patents

Abstract

The laser transmitter (1) is coupled to a section (2) of standard monomode optical fibre to whose free end a length (3) of fibre having higher attenuation is spliced. Another length of standard fibre (4) is spliced to the end of the attenuating section. The additional attenuation is secured by doping with a predetermined concn. of, e.g. trivalent titanium ions over a length of 10 cm to 10 m. Longer lengths can be wound into coils for ease of handling. USE/ADVANTAGE - Power reflected in laser transmitter reduced without incurring excessive cost or taking up too much space.

Description

The invention relates to an arrangement for damping the Light output in an optical transmission system from a light-feeding laser transmitter, a Transmission network consisting of optical fibers and one light-receiving diode, in which between Laser transmitter and receiving diode a section of an optical Fiber with a higher attenuation than that of the Optical fiber is optically connected.

A number of optical messaging systems are high Requirements for the stability of the emission properties of the Laser transmitter provided. This applies in particular to systems with optical overlay reception, for broadband systems in the Gigabit range and for analog messaging systems. Very pretty low intensities coming from the system into the laser transmitter can flow back, changes in the emission wavelength or the output power and thereby the Significantly reduce transmission quality.

The most important ones returning to the laser transmitter Intensity components are reflections on the optical ones Connectors and the Rayleigh scatter in Optical fiber.

With optical plug-in connections it was possible for Return loss values of over 50 dB can be realized. In the  However, practice can result from dirt or scratches on the optical contact surfaces in the connector there are clear deviations from this. In principle not the backscattered from the fiber material is avoidable Light output required for a 1 km long single-mode quartz glass fiber at a wavelength of 1300 nm is about 40 dB. To the Protection of the laser transmitter against returning Components of intensity are known which consist of a magneto-optical polarization rotator (Faraday Rotator) exist, which is arranged between two polarizers (Journal of Optical Communications 8 (1987) pages 18-21 and Laser Focus / Electro-Optics December 1988, pages 103-108).

The components used so far are either relatively large Arrangements of conventional optical components or Versions with integrated optics, the hybrid construction are combined with the laser in a housing. In The direction of attenuation is about 0.5 to 3 dB, in The blocking direction is 30-70 dB. These components are because of their large space requirements and the high costs for the economic expansion of optical networks up to the subscriber not suitable. Are cheaper in terms of dimensions hybrid components from a laser and an isolator in integrated optics. Because of the different Crystal systems that make up lasers (InGaAsP) and isolators (Lithium niobate) are manufactured, is an integration on a chip is not possible. With the practically implemented hybrid Construction is always a high cost for the precise Positioning and long-term stable assembly of the two Components may be required, which is correspondingly high costs entails.

Another disadvantage of conventional damping elements lies in the wavelength dependence of their blocking effect. So is the blocking attenuation, for example at a wavelength of 1550 nm 35 dB at 1250 nm only 10 dB. Furthermore, the  Barrier damping of conventional isolators also temperature dependent. A temperature change of 50 ° C can cause a Reduce attenuation by about 20 dB.

The optical isolator is an important component for analog optical messaging systems that are currently in the Subscriber access area are tested (OPAL test network the Telekom). While in all other levels of Telephone network is operated with digital technology, the Development of optical networks to participants from economic Founding in analog technology. The economic weight of this Development becomes clear when one considers that the Subscriber area around 80% of the total network of Telekom matters. Many professionals consider the use of Analog technology in the subscriber access area as one Interim solution due to cost considerations, the later is replaced by digital technology. This is justified with the well-known high transmission quality of digital systems in Wide area. With short transmission distances However, the situation is different: the analog technology could Subscriber access area in addition to lower costs also better Enable transmission quality.

EP 02 94 037 A1 describes an attenuator for the Use with fiber optic cables known, which consists of a section of a fiber that has a higher damping per unit length than that Attenuation of the signal-transmitting optical fibers. The increased attenuation of the fiber is achieved in that the Fiber is doped with metals that are different Can have values. The metal should at least partly in its lower value. The fiber has sections of normal fiber at both ends Attenuation, with the help of which the attenuator easily in an optical fiber can be spliced.

The present invention has for its object a Specify the arrangement with which the in the laser transmitter returning power can be dampened without such a measure would involve high costs or an excessive space requirement question. Furthermore, a component is to be provided be, which is easy and inexpensive to manufacture and without greater technical effort can be installed in transmission networks is.

This object is achieved with an arrangement of the aforementioned Art solved in that the section of the optical fiber with a higher attenuation directly to the laser transmitter or to the so-called pigtail of the laser transmitter is attached. Under a Pigtail becomes a short section of an optical fiber understood, the optical at the factory to the laser transmitter is coupled and at its free end usually the Optical fiber of a transmission network is spliced.

Those from the laser transmitter or from the end of the pigtail into the fiber radiated light output with higher attenuation this fiber and is attenuated by a predetermined value. All reflections and backscattering parts from the connected network back to the laser transmitter will be around subdued the same value. The main advantage of Invention is that the returning Intensity components before coupling into the laser transmitter higher damping fiber must pass again, overall double damping of the interference intensity is achieved. The cost of such an arrangement is compared to that of Components belonging to the state of the art are negligible low. The disadvantage, however, is that the transmission power significantly reduced according to the attenuation value of the fiber becomes. However, this disadvantage can be caused by a laser higher transmission power and / or a receiver with less Noise power can be compensated.  

According to a particularly advantageous development of the invention the section of the fiber runs with a higher attenuation curved over a certain length, preferably it is closed a coil wound. If a radius of curvature of z. B. 15 mm undershot, components can be manufactured whose Attenuation is wavelength-dependent and, for example, one One-way attenuation of 15.5 dB at 1300 nm and 60 dB at 1550 nm have, so a combination of attenuator and optical edge filter. By winding the fiber on cylinders with a rough surface, micro-kink losses can be generated, depending on the surface structure more or less are wavelength dependent and by means of the tensile force at Winding up the fiber spool can be varied within wide limits can. With radii of curvature of more than 15 mm the Damping curve independent of wavelength. The glass fiber can with these radii of curvature are wound into a coil, which reduces the space requirement and the protection of the sensitive fiber is improved.

The attenuation of the optical fiber is particularly advantageous with higher damping changeable by the curvature is changed. In addition to the fiber's own damping comes then a loss due to losses Microbends.

A component for use in the arrangement according to the invention is characterized by a laser transmitter, on which a Section of the optical fiber with higher attenuation is set directly. The optical fiber with a higher Attenuation is then used as a coupling fiber for the laser transmitter used. For further cuts it is advisable to free end of the optical fiber a section of a standard Single-mode fiber spliced or attached.

Alternatively, the component can be made from a laser transmitter with a attached section from a standard single-mode fiber  exist at the free end of a section of a fiber with higher damping is applied or spliced. The Backscatter attenuation of the splice connection is so high that No adverse effects to fear on the laser transmitter is.

Because the attenuation of the fiber depends on the length with higher attenuation and a certain value is generally specified, it is beneficial to the free end of the more damping Fiber to attach a section of a standard single mode fiber or splicing, on which the cuts for others Splice or plug connections can be made.

The main advantage of the components described is that to see that a fiber section is used that is like a Standard single-mode fiber spliced into the optical cable can be because both the mode field and the Outside diameter of the more damping fiber with one Standard single-mode fiber match. The usual The lengths used are between 0.1 and 10 m. The damping is then between 1 and 40 dB.

The invention is explained in more detail with reference to the exemplary embodiments shown schematically in FIGS. 1 to 3.

Figs. 1 to 3 show advantageous embodiments of a component, as is the teaching of the invention is used according to arrangements.

1 designates a laser transmitter to which a section 2 of a standard single-mode fiber is attached in FIG. 1. A section 3 of a fiber with higher attenuation is spliced onto the free end of section 2 . A section 4 of a standard single-mode fiber is spliced onto the free end of section 3 .

In Fig. 2, the section 3 of a fiber with a higher attenuation is placed directly on the laser transmitter 1 and takes the place of the commonly used coupling fiber (pigtail). A section 4 of a standard single-mode fiber is in turn spliced onto the free end of section 3 .

In Fig. 3, the section 3 is wound into a coil 3 a.

The fiber forming section 3 is an optical fiber, as is known for example from EP-02 94 037 A1. The core of the fiber is doped with certain metal ions, for example trivalent titanium ions in predetermined concentrations, so that a high absorption which is almost constant over a wide spectral range is produced. At a wavelength of 1300 nm-1600 nm, such a fiber has an attenuation of approximately 20 dB. The dimensions correspond to those of a standard single-mode fiber with an outside diameter of 125 µm and a mode field diameter of around 10 µm. This allows these fibers to be spliced onto standard single-mode fibers without any problems. As the absorbent fibers have the same refractive index profile as standard single-mode fibers, there is practically no jump in refractive index when spliced and therefore very little back reflection.

Compared to the isolators previously used, the before Laser arranged absorption fiber u. a. the advantages that the Attenuation over a wide spectral range is independent of the wavelength and also within a wide range Temperature interval remains almost constant. The Wavelength independence is therefore very practical Interest because optical messaging systems in the future probably operated with multiple transmission wavelengths become (wavelength division multiplex). Independence from the Temperature is for the use of these components in the  Subscriber area essential when installing in outdoor systems, the specifications also large temperature differences (-20 ° C to + 65 ° C) are observed Need to become.

Depending on the desired damping, lengths of 0.1 to 10 m can be used for the absorbent fiber. For longer lengths, it is recommended to wind sections 2 , 3 and 4 or 3 and 4 into a coil. Such a fiber spool is easy to handle, has small dimensions and offers the sensitive glass fiber sufficient protection against damage. If the coil falls below a certain diameter, curvature losses occur, ie the damping inherent in the fiber section 3 achieved by special doping can be further increased by winding it into a fiber coil over a small diameter (less than 30 mm).

By winding the fiber under tension on one Coil core with a rough surface can additionally Microbending losses are generated.

The use of section 4 from a standard single-mode fiber enables cuts to be made for further splice or plug connections. Since the length of section 3 remains unchanged, the damping of the component does not change.

Claims (8)

1. An arrangement for attenuating the light output from a lichteinspeisenden laser transmitter, a transmission network of optical fibers and a light-receiving receiving diode, wherein between the laser transmitter and receiver diode a portion than that of the optical waveguide in an optical transmission system comprising an optical fiber with a higher damping optically connected, characterized characterized in that the section ( 3 ) of the optical fiber with a higher attenuation is attached directly to the laser transmitter ( 1 ) or to the so-called pigtail ( 2 ) of the laser transmitter ( 1 ). 2. Arrangement according to claim 1, characterized in that the section ( 3 ) of the optical fiber with a higher attenuation is curved over a certain length, preferably wound into a coil ( 3 a). 3. Arrangement according to claim 2, characterized in that the attenuation in the section ( 3 ) of the optical fiber with a higher attenuation by curvature of the fiber can be changed, ie can be increased. 4. Component for use in an arrangement according to one of claims 1 to 3, from a laser transmitter ( 1 ) to which a section ( 3 ) of the optical fiber with higher attenuation is directly attached. 5. Component according to claim 4, characterized in that a section ( 4 ) of a standard single-mode fiber is spliced or attached to the free end of the optical fiber ( 3 ). 6. Component for use in an arrangement according to one of claims 1 to 3 from a laser transmitter ( 1 ) with an attached portion ( 2 ) of a standard single-mode fiber (pigtail) and one attached to the free end of the standard single-mode fiber ( 2 ) or spliced section ( 3 ) of a fiber with greater attenuation. 7. Component according to claim 6, characterized in that a portion ( 4 ) of a standard single-mode fiber is spliced or attached to the free end of the stronger damping fiber ( 3 ). 8. Component according to one of claims 4 to 7, characterized in that the length of the fiber ( 3 ) with higher attenuation between 0.1 and 10 m and its attenuation between 1 dB and 40 dB.