DE3019264C2 - Method of splicing multi-core optical cables - Google Patents

Description

50

The invention relates to a method for splicing multi-core optical cables by means of measurement splice attenuation using a pulse re-hectometer, which puts a pulse into the optical fiber has input optical transmitter and a reflection reproducing display device.

From "Philips Telecommunication Review", Volume 37, No. 4, September 1979, pages 241 to 249, a measuring device for optical cables is known which operates by means of a laser transmitter whose pulse-shaped transmission signal is coupled into the respective optical waveguide. Empfangsscitig, ie at the far Kabelendc is a corresponding Auswerteeinrichlung r.ngcschlossen including a display device for displaying ^ = de. Has measurement result, so it works as a pulse readjustment meter. In the case of a representation corresponding to the transit time of the echo signals, any interference points can be represented on a screen, for example by splice points, and the corresponding attenuation values can be determined.

When splicing multi-core optical cables, particular problems arise from the fact that, in many cases, z. B. v / hen cables have already been laid, attach the end of the cable is in a different location than the actual splice point. Since the measurement of the quality of the splice is just one can be done from the far end of the cable, is usually used to measure the splice points at both At the end of the measurement and at the end of the splice, an operator is required to carry out the necessary Manipulations of the adjustment devices and also the measured values for the respective transmits to another operator in a suitable manner

The present invention, which relates to a method of the type mentioned at the outset, lies in the The underlying task is to develop a measuring method of the type mentioned at the beginning so that the splicing of can only be carried out by one person and, moreover, the corresponding measuring processes are carried out relatively quickly can be. According to the invention this is achieved in that by means of the at the measuring end of the optical cable connected pulse reflectometer in a first measuring process of each optical waveguide of the cable by means of a first manipulator attached to the measuring end for optimal coupling of the Pulse reflectometer set and the associated coordinate values are stored that in one second measuring process from the end of the splice via a measuring line successively the stored coordinate values of the first manipulator is called up and automatically set for the individual fiber optic cables with a second manipulator located at the splice point, the location of the in each case to be spliced Adem is optimized in terms of splice loss in such a way that the am End of measurement for each individual fusion process of the second manipulator obtained attenuation measured values via the measuring line to the splice end transferred and displayed there.

In this way it is possible to carry out the necessary adjustments for the splicing of optical fibers to be carried out with a single operator, because the setting operations to be carried out at the end of the measurement determined in the course of the first measuring process and then stored. This like that Determined and saved setting values can then be called up one after the other from the end of the splice only a corresponding transmission for the control commands is necessary. These The transmission path can be provided in the form of a separate measuring cable (extension cable). One Another advantageous solution is that in each case one core of the optical cable to be spliced itself is used for feedback.

Further developments of the invention are given in the subclaims.

The invention is explained in more detail below with reference to drawings. It shows

Fig. 1 in a block diagram of an embodiment of an arrangement for implementing the invention Procedure,

F i g. 2 the structure of an optical switch,

3 shows the backscatter curve of an optical waveguide with a splice point,

F i g 4 the remote control available at the splice end

in'chuing.

In Fig. 1 isi a multi-core optical cable with LWK \ designated, which is to be connected at the left end (splice end) by means of a suitable splicing device (z. B. by welding) wire by wire with another optical cable LWKQ . At the measuring end of the optical cable LVWCI facing away from the splice, a manipulator MA is provided which, for. B. in η parallel V-grooves Kl to Vn the n-Lichtwellei.ieiter fibers of the optical cable JLVVTi 1 arranged side by side or in some other predetermined configuration and their ends for connection to a laser transmitter and receiver containing optical pulse reflectometer (OTDR), which is labeled RM , provides. In detail this z. B. successively coupled to the connection points VI to Vr / of the n- fiber optic fibers of the fiber optic cable LWK 1 via a Lanse OL. This is carried out by means of the manipulator MA , which can be moved in three coordinate directions x, y, ζ and z. B. is set via three corresponding Stelimotore.

In detail, the procedure is in a predetermined order, for example, so that first the connection V1 is made to the first wire of the cable LWK 1, for which a certain combination of coordinates AfI, y \ and z \ of the manipulator MA is required. The Pulse RM is connected via the manipulator MA so that achieved at the oscilloscope OG, which represents the backscatter signal and echo signal corresponding to the 3 shows at A a maximum amplitude value. This means that the transition to optical waveguide fiber No. I takes place with the least possible attenuation. The positions x \, y \, z \ obtained as a maximum for the respective optical waveguide are entered into a computer RE and stored there. Proceed in the same way for the remaining wires up to Vn .

In a second measuring process, the position of at least two scanning pulses a and b is determined by means of a backscatter curve (cf. NTZ, volume 31, 1978, pages 144 to 146) according to FIG. In this case, the scanning pulse a, as seen from the end of the measurement, lies shortly before the splice point in terms of time and the scanning pulse b, in terms of travel time, lies shortly after the splice point. It is expedient to provide a third sampling pulse c , which defines the zero line (reference value) and, in terms of transit time, lies after the end of the optical cable LWTiO. The amplitude value C ₁ belongs to the sampling pulse, to the sampling value b the amplitude value B (immediately after the splice point) and to the sampling value a the amplitude value A (immediately before the splice point).

These sampling pulses a, b, c, which are displayed as corresponding signals on the oscilloscope OG and which can be adjusted or shifted accordingly in terms of time, are also sent from the scanner AT (sample and hold circuit) to the computer RE and there in their temporal position recorded. For a certain cable LWK 1 it is usually sufficient to save the values a, b and c once, since they can be used for all fiber optic cables of the cable LWK \ .

After these setting processes have been carried out, the positioning values x \, y \, 7. \ To xn, yn, zn of the n- optical waveguide fibers are stored in the computer RE together with the corresponding time values for the scanning pulses a, b. c saved before. With this, all necessary measured values are obtained, which are at the end of the measurement

on the one hand, for coupling the pulse reflector RA to the respective optical waveguide fiber, as well as the scanning pulses a, b, c, which are necessary for measuring the splice point.

After these preparatory measuring processes have been carried out at the end of the measurement, the actual splicing process, which takes place at the end of the splice, can be carried out. For this purpose, a transmitter SE is provided at the measuring end, which is connected to the computer RE and whose output is led to an optical switch VV £. This switch has an output led via the receiver EM to the computer RE. The computer RE is connected on the output side to the manipulator MA .

A corresponding measuring line is to be provided between the measuring end and the splicing end, which in the present example is shown as a separate line ML . However, it is also possible to measure with the lines to be spliced or with one of the fibers of the optical cable LWKi itself. In this case, a line connection that has to be specially established is analogous to the additional line ML never '; necessary. However, the last splicing process to be carried out must then be carried out without monitoring, because there is no longer any measuring line available for this purpose. In many cases, however, especially in the case of optical cables, some additional fibers are provided as a reserve, so that the optical cable LWK to be spliced can be used as a return line for the measurement process even with a fiber as a return line without major difficulties.

The structural units provided at the splice end are identified by adding the letter 5. A switch WES is first connected to the connecting line ML , the output of which is led to a receiver EMS , while its input is connected to a transmitter SES . Details of a possible structure both for the switch WE at the Mpßende and for the switch WES at the splice end are shown in FIG. 2, where a connection for the transmitter SE or 5ES is drawn on the left in a schematic representation. The electrical signals present there are converted into optical signals by a light-emitting diode LED and fed to a lens L1. A part of the optical transmission signals reaches the measuring line ML via a 50% mirror SP via a further lens L 2 and from there to the respective other switch circuit. The signals coming from the connecting line ML are fed via the lens L 2 and the mirror SP as well as a further lens L 3 to a photodiode FOD and from there fed as electrical signals to the respective receiver EM at the measuring end or EMS at the splicing end.

If the line ML is designed as an electrical line, electrical switch circuits constructed in an analogous manner are to be provided.

A display device AZS is connected to the receiver EMS at the splice end and essentially displays the information about the amplitude values A and B and / or about the attenuation values of the splice in FIG. 3 on the oscilloscope OG at the measuring end. It is thus easily possible for the operator at the splice end, by looking at the display device AZS , to continuously record the quality of the respective splice connection and to observe the effect of any changes.

A transmitter SES is also connected to the switch WES , which transmits the signals from a remote control

lung FBS signals coming / transmits to MeUende. Furthermore, the actual splicing device VBS is provided, which z. B. can be designed as a welding device or as a mechanical clamping device. At the end of the splice there is also a manipulator MAS , the coordinate values of which are designated with .v ', y' and z '.

At the end of the splice, the procedure for carrying out the splicing process is as follows: The operator controls the η operator via the transmitter SES by means of the remote control device FBS. the WFS switch. the connection line ML. the switch W / T and the receiver EM. the computer RF , which according to the stored coordinate value χ 1. ν I, z \ for the fiber no. I, the positioning of the: optical waveguide no. Thus, at the end of the measurement, the measuring device is prepared for the measurement of fiber no. I, the setting to the maximum at the end of the measurement having already been carried out.

Via the remote control FBS is at the measuring end .ή by the receiver FM, the time domain RM activated and are pulsformige measurement signals on the fiber optic cable LWK 1. Depending on the quality of the connection point between the optical waveguide. No. I of the light waveguide cable L WK 0 and the Lichtwel-. lenleiter # 1 of the optical cable LWK 1 is the amplitude jump at the splice in accordance with Fig 3 of a certain size.. The coordinate values, for example x'X.y'X and / '\ for the first fiber are now changed in the manipulator MAS at the end of the splice until this jump, ie the difference between the amplitude values A and B according to FIG. 3 becomes as small as possible.

If necessary, signal A can first be activated and the manipulator MA can be changed again (for readjustment) until A becomes a maximum. This process is only necessary if the value for A originally set and saved with \ I. \ I. ζ I has changed in the meantime. Then the signal B is called. ie the measurement after the splice is carried out and the manipulator MAS changes until the signal B also has a maximum. When these two maxima, ie the maximum of A and the maximum of β for fiber no. 1, are reached , the splicing process can be carried out, for example by gluing, welding connections or the like.

It .st possible, after the actual splicing process has been carried out, the splice attenuation, ie the difference between A and B according to FIG. 3 to determine ifi and to register in the computer RE. For this purpose, a corresponding control signal can be issued by means of the remote control FBS after the actual splicing process has been carried out and with the pulse reflectometer AM the splitting attenuation is then determined in the computer RE and recorded or displayed by appropriate recording devices.

In an analogous manner, the respective maximum of B and possibly A (if necessary) is now set for the remaining fiber optic fibers No. 2 to η from the splice end from κι, ie the splice attenuation is minimized and the splicing process is then carried out.

At the end of the process, all the light waves i to η of the optical cable LWKX are connected to the individual fibers of the optical cable LWKO , with as little attenuation as possible. With the method described above, the splitting of multi-core optical waveguide cables can be carried out quickly and reliably by just one operator in a relatively simple manner, with the expense of equipment being kept relatively small.

The setting of the manipulator Λ-M.S takes place in present example by hand. However, it is also possible here to do an automatic maximization to expire.

The manipulator MAS can / .. B. also be designed only in the form of a simple adjustment device for an adhesive splice (with V-Nule: l.

F i g. 4 shows the operating field for the control device FBS and the display device A / S. The respective amplitude value of A or B appears in a display field AFX , depending on whether key TA (for signal A) or key TB (for signal B) is pressed. The impuisrefiekiomeiei RM eiii- uuev can be switched off using the TRM key. In a preselection field VW , the individual fibers 1 to ^ are set using appropriate buttons (not shown here).

Using the preselection field VW , the corresponding values \ 1, y 1, ζ I to \ n are thus obtained at the end of the measurement. yn. zn of the n-fibers of the optical cable are provided. In the present example it is also assumed that the manipulator MA present on the Miesterde can also be operated with the remote control device FBS.

Adjustment devices Tv, Tv. Tz and Tv *. Ty * and Tz * are provided, where the former are an increase in the respective value ν. ν and ζ of the manipulator MA and the latter cause a reduction in size.

At the end of the splice, the operator only needs to enter the necessary control commands on the control panel shown in FIG. 4 and thereby carry out the splicing process. After the completion of the respective splicing process, the splice attenuation (in the present case 0.2 dB) can be displayed for a specific optical waveguide via a second display field AF2.

The splice attenuation can be evaluated from the sampled values A. Sund Γ obtained using the following formula:

log

-1 -

B-C,

F) -

α ,. I ₁

It is

AB C =

Splice loss (in dB)

Measured values at the times from c

Average fiber attenuation without splice (in

dB / km)

Distance between sampling pulses a and 6 (in km.

/ i = 0.1 km corresponds to about 0.1 .us).

The mean attenuation of the optical waveguide λγ can either be carried out in a separate measuring process ζ. Β. be determined before starting the splicing work. Another solution is more practical and simpler, in which, in addition to the samples A and B, two additional samples A * and B * are obtained before and after the splice, so that there are two measured values before the splice and two measured values after the splice. From the difference between the values -4 and A * or B.

and ß * can be omitted because the / wisrhcnlicgcndc path length the time difference is known. Calculate the mean attenuation of the respective fiber optic cable.

The calculation of the individual attenuation values and the storage z. B. the value \ / is expediently carried out by means of the computer IUi.

The work of the operator can advantageously be simplified because the control panel according to FIG. 4 the amplitude values A and B are converted linearly into corresponding frequency values, ie

there is a direct relationship between the respective frequency and the respective amplitude value. These frequencies can e.g. B. can be made audible via the connections KH 1 and KH 2 by means of headphones and the operator can see directly from the frequency difference between the measurement at amplitude value A and the measurement at amplitude value B how great the splice loss is.

llier / u 3 sheet drawings

Claims (5)

Patent claims: 1. A method for splicing multi-core optical cables by measuring the splice attenuation using a pulse reflectometer which has an optical transmitter inputting a pulse into the optical waveguide and a display device which reproduces the reflection, characterized in that connected by means of the at the measuring end of the optical cable (LWKX) Pulse reflectometer (RM) In a first measuring process, each optical fiber of the cable (LWKX) is set to optimal coupling of the pulse reflectometer by means of a first manipulator (MA) attached to the measuring end and the associated coordinate values (x, y, z) are stored, that in a second measuring process from the end of the splice via a measuring line the stored coordinate values (xy z) of the first manipulator (MA) are called up one after the other and automatically set for the individual optical waveguides, with a second manipulator (MAS) located at the splice point, the position of the respective topl The splice attenuation of the tearing wires is optimized in such a way that the attenuation measured values obtained at the measuring end for the individual positioning processes of the second manipulator are transmitted via the measuring line to the splice end and displayed there. 2. The method according to claim 1, characterized in that d & ß from the splice end a readjustment of the coordinate values initially determined and stored at the measuring end! (x, y, z) is made. Ji 3 Method according to one of Claims 1 to 2, characterized in that the measuring line is a core of the optical cable (L WK 1). 4 The method according to any one of claims 1 to 3, characterized in that the display on Splicing is done optically by transmitting the display of the pulse reflectometer. 5. The method according to any one of claims 1 to 3, characterized in that the display on Splicing acoustically by transmitting the into a <5 Frequency converted display of the pulse reflectometer takes place.