SE519255C2 - ADD / Drop node for low loss WDM - Google Patents

Abstract

An add/drop (7) node for an optical fiber network of WDM type has preamplifiers (19, 21) connected to the input fibers (3, 11). Part of the incoming signal power is tapped off by means of drop couplers or splitters (47, 49) and the tapped-off power is provided to a demultiplexer (51) where WDM information channels to be extracted from the network in the node are separated from each other and then fed to opto-electrical receivers (15). WDM information channels to be added in the node from electro-optical transmitters (17) are first combined in a multiplexer (61), the resulting signal being provided to add couplers (57, 59) to which also the signals incoming to the node are provided so that a combined signal is obtained for transmission to the opposite side of the node (7). Channels are thus added in the node to channels passing substantially ininterruptedly through the node. In order to have a low attenuation of the passing signals, the power per channel in the added signal is given approximately the same level as the power of each passing channel by an optical amplifier (65, 67) arranged in the input line to the add coupler from the multiplexer (61). By this arrangement it is possible to maintain a low attenuation of the passing signals within the optical add/drop node, since no extra attenuating devices are needed for the light signal containing the passing channels. The signal to noise ratio of these channels can thus be kept high.

Description

35 40 519 255 2 o i s o ø | n n ~ | ; a «| now A previously known version of an add / drop node with a blocking drain function is shown in fi g. 2. The optical WDM traffic enters the node through an optional optical preamplifier 19, 21. Each wavelength is filtered out in a DEMUX element 23, 25, which separates the signals, so that on each of the plurality output from DEMUX : only one channel is transmitted, ie information contained in light within a single wavelength range. Drained channels are fed to receiver 15 via 27s 27, 29 from the DEMUX to the respective receivers and channels to be added as well as passing channels are fed to a MUX element 31, 33, which has its corresponding input terminals connected via fibers 35. , 37 from the transmitters 17 with the MUX 31, 33 and the other input terminals connected to the output terminals of the respective DEMUX 23, 25 for the same transmission direction through the node via the fibers 39, 41. The WDM traffic at the output of the MUX 31, 33 is fed to an optional optical power or power amplifier 43, 45 and from there to the corresponding fibers or the corresponding cable 1, 13.

The disadvantage of this solution is that it is based on a relatively large number of cascaded filters (DEMUXs and MUXs), if a large number of add / drop nodes are present in the network. A further disadvantage is that a non-blocking drain function cannot be achieved.

Another embodiment of an add / drop node, which can be designed for either blocking or non-blocking drain function, is shown in fi g. The WDM traffic entering the node 7 is amplified in an optical preamplifier 19, 21 and then divided into a drain coupler 47, 49. This coupler is an optical power splitting device which supplies a part of the total signal power of The WDM traffic to a DEMUX 51, which filters out each channel, some channels of which are then transmitted to optoelectric receivers 15. The second part of the split signal is fed to optional wavelength blocking filters 53, 55, mixed in an additional coupler 57, 59 with the new traffic to be transmitted from electro-optical transmitters 17 via a MUX 53 and thus added to the node 7, and then fed to an optical power amplifier 43, 45. By arranging or not arranging the blocking filters 53, 55, the node is obtained to work in a manner with a blocking or non-blocking drain function.

The disadvantage of this second solution is that it adds a lot of noise to the passing signals. The reason for this is that the optical output power per channel from the MUX 61 is very low compared to the output power from the optical preamplifier 19, 21 and thus the attenuation in the drain switches and the additional switches 47, 49; 57, 59 be high for the passing signals to keep them at the same power as the added channels after the additional coupler 53, 55.

DESCRIPTION OF THE INVENTION It is an object of the invention to provide an add / drop node for a fiber optic network which has a low drain loss for the traffic channels passing through the node.

The problem to be solved by the invention is thus to provide a WDM network and an add / drop node for this, which only attenuates the power of WDM channels which pass through the node only to a small extent, the attenuation being essentially only the attenuation, which results from the power reduction required to drain sufficient total signal energy to output the WDM channels which terminate in the node.

In the construction of such an add / drop node, which is of the type with an additional coupler for adding channels, which in the node are added to the channels which pass substantially uninterruptedly through the node, the basic idea has been to have a low attenuation for the passing signals, the power per channel in the added signal having to have approximately the same level as the power of each passing channel, at the input of the additional switch. This is achieved by arranging an additional optical amplifier in the input line to the auxiliary coupler, on which the light signal, which constitutes the carrier for the added channels, is fed to the auxiliary coupler.

The light signal comprising the added channels is generally generated by electro-optical transmitters and an optical wavelength multiplexer, and then the additional optical amplifier is arranged at the output of the multiplexer. By this arrangement it is possible to maintain a low attenuation of the passing signals within the optical add / drop node, since no additional attenuating devices are required for the light signal containing the passing channels.

As a result, the signal-to-noise ratio of these channels can be maintained high.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described as a non-limiting embodiment with reference to the accompanying drawings, in which - frg. l is a general schematic view of a simple WDM type optical fiber network with known add / drop nodes, - fi g. 2 is a block diagram of a prior art add / drop node for a WDM optical network, which only allows blocking drain function, - fl g. 3 is a block diagram of a prior art add / drop node for a WDM optical network, which allows both blocking drain function and non-blocking drain function, - fi g. 4 is a block diagram of an add / drop node for a WDM optical network having a better signal-to-noise ratio for signals passing through the node than those in fi g. 2 and 3 showed the nodes.

DESCRIPTION OF THE PREFERRED EMBODIMENT The construction of an add / drop node to be used in WDM optical networks, for example of the basic type shown in Fig. 1, and having a high signal-to-noise ratio, is illustrated by the block diagram in ñg. 4. Here is the optical power amplifier of the prior art solution according to fi g. 3 replaced by a two-stage configuration, comprising an optional second stage.

Thus, an optical add / drop node is displayed for adding and removing or draining wavelength multiplexed (double-WDM) traction channels in a fi beroptic network in fi g. 4. The node can be configured for either blocking or non-blocking drain mode. A left line cable 1 comprising two optical fibers 3, 5 for transmitting light signals in both directions is connected to one side of the optical add / drop node 7 and the other side of the node 7 is connected to the two fibers 9, 11 of a right line cable 13. The node 7 comprises or is connected to receiver 15 and transmitter 17 for converting optical signals into electrical signals and vice versa, the electrical signals being transmitted to or respectively received from other devices, links or networks, not shown.

The optical WDM track enters the node from both sides thereof on input lines 3, 11 and is amplified in optical preamplifiers 19, 21. The WDM track on each line is then divided into drain couplers 47, 49, which are connected to the output terminal. the inference from the preamplifier array. Such a drain coupler is an optical power splitting device which supplies a portion of the total amplified signal power of the WDM traffic to an optical DEMUX (demultiplexer) 51. When the network is suitably constructed so that never the same channel arrives from both sides of the node, only one DEMUX is used with an optical coupler on its input side. Each wavelength path is filtered out in the DEMUX element 51, which thus separates the optical channels, so that on each of the numbers output from the DEMUX only one channel is transmitted, ie information carried by light within a single wavelength range. Some channels of the WDM track are then transmitted to optoelectric receivers 15.

The second part of the divided total signal, which arrives on one side of the node 7, can then be fed to optional wavelength blocking filters 53, 55, which are arranged to block the light of the wavelength intervals which are transmitted from the DEMUX 51 to the receivers. 15.

By arranging or not arranging the blocking filters 53, 55, the node is made to work with blocking draining modes or non-blocking draining modes.

The second part is thus transmitted either directly or via the filter 53, 55 transmitted to an input of an additional coupler 57, 59. In the additional coupler it is mixed with the new traffic channels to be transmitted and originates from the viewed node. These optical channels to be added are generated in electro-optical transmitters 17 and are formed to form a light signal in a MUX (multiplexer) 53 connected to the outputs of the transmitters 17. The composite signal thus obtained is amplified to a suitable power level in an optical amplifier 61, 63. The power level is adjusted so that the individual power levels of the channels to be added are as equal as possible to the power levels of the channels which continue in a substantially uninterrupted manner through the node 7 from a line cable 1, 13 to the opposite 13, 1. The amplified signal, which is emitted from the amplifiers 61, 63, is sent to the second input terminal of the auxiliary coupler 57, 59 and in this way the new traction channels are added or combined with the channels which continue through the node. The resulting light signal is then fed to the input end of the corresponding optical cable 9, 5 the lead cable 13, 1 on the opposite side of the node. When the power level of the signal emitted from the auxiliary switch is not sufficient to obtain a satisfactory information transmission, due to large attenuation in the section to which the light signal is transmitted, the light signal originating from the auxiliary switch 57, 59 is amplified in an optical power amplifier 43, 45, which is thus optional. From the output terminal of the power amplifier 43, 45, in this case, the amplified light signal is fed to the input end of the optical beams 9, 5 in the line cable 13, 1 on the opposite side of the node 7.

Claims (2)

51 9 2 5 5? E? 321? - 312? - Li 51 5 PATENTKRAV A node for adding and draining traffic channels for an optical fiber network, the node being arranged to be connected to two first optical fibers, each of which carries an incoming WDM light signal, which two incoming WDM light signals propagate in opposite directions and each comprises a plurality of WDM information channels incoming to the node, and with two corresponding other optical fibers, each carrying a WDM light signal emanating from the node, which two outgoing WDM light signals are propagated in opposite directions and each comprises a plurality of WDM information channels transmitted from the node, pairs being formed by a first optical fiber and a second optical fiber, so that optical fibers in a pair carry WDM light signals, which propagate in the same direction, and the node comprises 15 an optical preamplifier for each pair coupled to an output end of the first optical fiber in the pair to amplify the incoming WDM light signal carried by the first fiber. in the pair, - a drain switch for each pair with an input terminal connected to an output terminal of the optical preamplifier, which is arranged for the pair, and with two output terminals for dividing the light signal input to the drain switch into a first part of a an output terminal and another part of another output terminal, an additional switch for each pair of two input terminals, one input terminal of which is connected to an output terminal of the drain connector provided for the pair, the additional connector having an output terminal to the second optical fiber in the pair, ao- a single combining coupler with two input terminals, of which a first input terminal is connected to an output terminal of the drain coupler in a first of the pairs to receive the second part therefrom and a second input terminal is connected to the drain coupler in a second of the pairs, which is separate from it first pair, to receive the second part from this drain coupler, - a single demultiplexer with an input terminal connected to an output terminal of the combining coupler to receive the combined second parts therefrom and to filter, 5 19 25 išëzšï: -aß: ; :: ~: = :::; 2e to separate WDM information channels in the incoming WDM light signals from each other to transmit them on separate output terminals from the demultiplexer, - a single multiplexer with an input terminal for receiving sWDM information channels for combining them on an output terminal, - a single light-dividing coupler with an input terminal connected to the output terminal of the multiplexer for dividing light received from the multiplexer into two substantially equal parts 10 emitted on two output terminals of the light-dividing coupler, of which a first output terminal is connected to an input terminal of the auxiliary coupler, which is arranged for the first the pair, and a second output terminal is connected to an input terminal of the auxiliary coupler, which is arranged for the second pair, so that in the auxiliary coupler for a pair at least one WDM information channel in the WDM light signal entering the first fiber of the pair, this at least one WDM information channel passing through the node in a substantially uninterrupted manner, and at least one WDM information channel added in the node being combined to a light signal which is transmitted to the other optical fiber in the pair, characterized by - amplifying means for amplifying it light signal, which appears on an input terminal of an additional switch and carries the at least one, second WDM information channel, which is to be added, so that the power levels of each such other information channel on this input terminal are substantially equal to the power levels at each of the at least one WDM information channels passing through the node, also at an input to the auxiliary coupler, and a blocking filter for each pair connected between an output end of the first optical fiber in a pair and an input terminal of the auxiliary coupler provided for the pair to block selected WDM information channels from passing through the node. Node for adding and draining traffic channels according to claim 1, characterized by a power amplifier for each pair, wherein a power amplifier for one pair is connected to an output connection from the additional coupler, which is arranged for the pair, to amplify the power. of the light signal to be transmitted to the other optical fiber in the pair.