NO158967B - ERROR LOCATION DEVICE FOR A LIGHT WAVER WIRE CABLE. - Google Patents

Description

A fault location device for a light wave

conductor-cable stretch, where the device comprises wave-

length-selective coupling means (6, 7) which only disconnect

signals with at least one specific wavelength from a light

waveguide (3) for one transmission direction and on

new lnncouples these signals in a second light waveguide

(4) for the opposite direction of transmission. Signals with

other wavelengths are led by the coupling means

in its normal direction of propagation.

The invention relates to a fault location device for a light waveguide cable section, where the device disconnects a signal from a light waveguide arriving from a transmitting-receiving device, and connects this signal to a second light waveguide which leads the signal back to the transmitting-receiving device.

A fault location device of this type is known from DE-OS 3 042 815. In this device, the redirection of the fault location signal from one transmission direction to the opposite transmission direction takes place in the optical intermediate amplifiers. The signal is disconnected from the optical transmitter for one transmission direction and reconnected in the optical receiver for the opposite direction. With this device, special connection measures are necessary in order to provide the connection between the transmission line in the event of a mislocation. forward and return direction. In the event of a fault location, it is also impossible to maintain the normal signal transmission operation at the same time.

The purpose of the invention is to provide a fault location device of the type indicated at the outset which, with simple means and without connection technical costs, enables a quick fault location on a light waveguide cable stretch.

The above purpose is achieved according to the invention in that the fault location device comprises wavelength-selective coupling means which only disconnect signals with at least one specific wavelength from the light waveguide for one transmission direction and reconnect these signals in the light waveguide for the opposite transmission direction, and that the coupling means forward signals with other wavelengths in their respective propagation direction.

Appropriate embodiments of the invention are indicated in the dependent claims.

The invention shall be described in more detail below

in connection with design examples with reference to the drawing, where fig. 1 shows a light waveguide cable section with several fault location devices, fig. 2 shows a £eil~ locating device whose coupling means consist of plane-parallel plates, and fig. 3 shows a fault location device

ning if the coupling means consist of light waveguide branches.

In fig. 1 shows an optical transmission path where a transmitting-receiving device 1 is connected via a light waveguide cable to a receiving-transmitting device 2. In the cable, a light waveguide 3 ensures the transmission of optical signals from the transmitting-receiving device 1 to the receiving-transmitting device 2, and a second light waveguide 4 ensures the transmission of optical signals in the opposite direction.

In order to be able to more accurately locate faults that may occur on the cable route, fault location devices 5 are inserted into the cable at certain distances. The light waveguides for the individual cable sections are either permanently or releasably connected to the fault locator by means of plugs 6, 7 -lization devices 5.

The fault location devices are equipped with wavelength-selective coupling means. These cause an optical signal arriving from one direction of transmission with a specific wavelength to be reflected and redirected to the opposite direction of transmission. In this way, a signal sent from the transmitting-receiving device 1 is again supplied to it. A comparison between the transmitted signal and the re-received signal then shows whether a fault exists on the cable route between the sending-receiving device and the fault location device. Signals with wavelengths other than the wavelengths for which the fault location device is tuned for reflection pass through the coupling elements unimpeded.

If you tune all the fault location devices installed on a cable section to a different wavelength, the individual cable sections can be checked one after the other and a fault can thus be located in a completely accurate way.

As the error localization devices only reflect a respective signal with a fairly specific wavelength and transmit signals with other wavelengths, during the localization process it is possible to maintain a signal transmission between the end devices of the cable route, namely on the signal wavelengths that the error localization devices transmit.

Such a fault location device also proves to be very advantageous when installing a light waveguide cable stretch. At the end of a laid-out cable section, the fitter connects a faulty local i<serin<gsanor.dnin<g.. From a transmitting-receiving device at the beginning of the cable route, a test signal is then emitted which the fault locating device reflects. The fitter is then notified whether the cable section just laid out or installed is faultless or not, so that he can take appropriate measures. This information is transmitted on a wavelength that the fault location device transmits. The fitter can receive the information with a receiver that is tuned to this wavelength and is connected behind the fault location device.

In fig. 2 is a schematic representation of an exemplary embodiment of a fault location device. The coupling means in this fault location device consist of two plane-parallel plates 6 and 7 (interference filter) which reflect light with a specific wavelength and are permeable to all other wavelengths. One plane-parallel plate 6 is here inserted into the transmission path of the light waveguide 3, and the other plane-parallel plate 7 is inserted into the transmission path of the light waveguide 4. The plates 6 and 7 are inclined in such a way in relation to each other and to the transmission paths of the light waveguides 3, 4 (solid lines) that a light beam (shown dashed) with a specific wavelength from the light waveguide 3 is reflected on the first plate 6, from there it is redirected to the second plate 7, here is reflected again and coupled into the light waveguide 4 for the opposite direction. Light rays with other wavelengths in the light waveguides 3, 4 (solid lines) pass through the plane-parallel plates unimpeded.

Another embodiment of a fault location device shown is shown in fig. 3. The coupling means here consist of wavelength-selective light waveguide branches, such as are known for example from DE-OS 3 135 312. The light waveguide 3 coming from the transmitting-receiving apparatus radiates several signals with different wavelengths on the end surface of a second, continuing light waveguide 3'. The 3' end surface of the light waveguide is provided with a layer that is impermeable only to rays with a fairly specific wavelength (dashed line). These rays are reflected on the end surface and are coupled into a third light waveguide 8, while, on the other hand, all other rays (solid line) penetrate through the layer of the end surface and propagate further in the light waveguide 3'. With the light waveguide 8, the reflected rays are transferred to a second wavelength-selective light waveguide branch. The light waveguide 4' is also provided on its end surface with a layer which is impermeable to the rays transmitted from the light waveguide 8. These rays are redirected at the end surface of the light waveguide 4" and are fed into the light waveguide 4 above which they return to the transmitting-receiving device. The rays arriving over the light waveguide 4<1> penetrate the layer on the end surface and are directly coupled into the continuing light waveguide 4.

Claims (4)

1. Fault location device for an optical waveguide cable section, where the device disconnects a signal arriving from a transmitting-receiving device from an optical waveguide, and connects this signal in a second light waveguide which leads the signal back to the transmitting-receiving device, characterized in that it comprises wavelength-selective coupling means (6, 7, 8) which only disconnect signals with at least one specific wavelength from the light waveguide (3) for one direction of transmission and again, these connect signals in the light waveguide (4) for the opposite direction of transmission, and that the coupling means forward signals with other wavelengths in their relevant direction of propagation. 2. Fault location device according to claim 1, characterized in that several such fault location devices (5) are arranged at a distance from one another within a cable section, the coupling means in each fault location device disconnecting a signal with a different wavelength from the light waveguide (3) for one transmission direction and again this switches the signal into the light waveguide (4) for the opposite transmission direction. 3. Fault location device according to claim 1, characterized in that the coupling means consist of two plane-parallel plates (6, 7) which reflect signals with at least one specific wavelength and transmit signals with other wavelengths, and that one plate (6) is inserted into the light transmission -the path for one direction and the other plate (7) are inserted into the light transmission path for the other direction, the two plates being inclined in such a way in relation to each other and to the light transmission paths that light for one transmission path that is reflected by one plate , is diverted to the second plate, reflected there and connected to the opposite, second transmission path. 4. Fault location device according to claim 1, characterized in that a light waveguide branch (3, 3', 8, 4, 4') is inserted in each of the two transmission paths. and that the light waveguide branches are optically coupled to each other.