SE509807C2 - Device at add / drop node in a path length multiplexed optical communication system. - Google Patents

Abstract

An add/drop (7) node for an optical fiber network of WDM type has preamplifiers (21, 23) connected to the input fibers (3, 11). Part of the incoming signal power is tapped off by means of drop couplers or splitters (45, 47). The tapped-off power is provided to demultiplexers (49, 51), one demultiplexer being used for each direction, in which WDM information channels are separated from each other. The output signals of the two demultiplexers which comprise the same wavelength interval are combined in combining couplers (73, 75, 77) and then fed to optoelectrical receivers (15), where the information of the dropped channels is converted to electrical signals. In order to monitor and maintain a satisfactory transmission quality of the signal from the node (7), the optical power in each wavelength channel of the multiplexed light signal transmitted in the network is measured, independently for west and east traffic, by adding splitting couplers (61, 63, 65; 67, 69, 71) to the outputs of the demultiplexers (49, 51). These splitting couplers deflect a portion of the signal power to optical power detectors (53), which provide signals informing on the individual power levels. This design gives a node having a minimum number of multiplexers and also the node has a better performance in failure states. WDM information channels to be added in the node from electro-optical transmitters (17) are combined in a multiplexer (29), the resulting signal being split (31) and provided to add couplers (33, 35) to which also the signals incoming to the node are provided.

Description

509 807 2 25, 27 are connected to each other, so that traction channels can pass through the node in a substantially uninterrupted manner. The output connections from the dry amplifier arrays 21, 23 and the input connections to the power amplifiers are also connected to input ports of optoelectric receivers 15 and electro-optical transmitters 17, respectively, via an internal network of couplers and demultiplexers.

Traction channels T1, ..., T3, which originate in the considered node and come from the transmitters 17, are combined in an optical coupler or optical multiplexer 29, also called wavelength multiplexer. The combined signal is divided into another coupler 31 into two signals, each of which has substantially the same power as the other channel, and these two w signals of equal power are introduced into the ring paths in both western and eastern directions by means of couplers 33. , 35, which are arranged in the connecting line between the output connection of a preamplifier 21, 23 and the input connection of a power amplifier 25, 27. Correspondingly, a part of the path length multiplexed signals which arrive at the node 7 is disconnected or drained from the eastern and western directions by means of couplers 37, 39, ice which also. are arranged in the connecting line between the output connection from a preamplifier 21, 23 and the input connection to a power amplifier 25, 27. The drained signals are combined in a coupler 41, before they are demultiplexed in individual traction channels R1, ..., R3 by means of a path length multiplexer 43, the input terminal of which is thus connected to the coupler 41 and the output terminals of which are connected to the input terminals of the optoelectric receivers 15.

In order to monitor and maintain a satisfactory transmission quality, it is advantageous to monitor the optical power in each path length channel of the WDM light signal or multiplexed signal which is transmitted in the ring network. The optical power must be measured independently for western and eastern traffic. The typical mechanism by which this can be done is to use additional wavelength demultiplexers to divide the multiplexed WDM light signal or the multiplex signal into its individual path length channels and then convert the optical power in each channel into an electrical signal with using a variety of optical power detectors. This is degraded in fi g. 2, in which electrical quantities, representing effects PIW, ..., P3W; P1E, ..., P3E of channels arriving from the west and east, respectively, are derived from additional couplers 45, 47, which are connected in the connecting line between the output connection from a preamplifier 21, 23 and the input connection to a power amplifier 25, 27, preferably directly at the output terminal of the respective preamplifier. These couplers 45, 47 are connected to input terminals of wavelength multiplexers 49, 51, which have their output terminals connected to the inputs of associated optoelectric detectors 53, 55, as which emit said channel effects or channel strengths.

The prior art method has various disadvantages. These include a) a need in the node to include two path length multiplexers, each of which is an expensive device that requires heat stabilization and overflow, and b) that the structure includes "common failure modes" by all drained pull channels are vulnerable to faults in the wavelength demultiplexers 43 connected to the receivers 15 or the combining couplers 37, 39. Your western / eastern channels, which take without proportion of the incoming signal to be combined, in the coupler 41, which is connected to the input terminal of the multiplexer 43. t KNOWN Intrum I US U.S. Pat. No. 5,510,917 discloses an optical communication monitoring and control system for monitoring traffic in bidirectional optical communication networks. In each node, the signal is drained in fi brema and the power of the signal is measured. Then a wavelength detector is used for each direction. In addition, an additional demultiplexer is used to separate the wavelengths w, before the respective signals reach the receivers. This description corresponds in some details to the undisunited pre-recognized anodizing unit. 2.

The published international patent application WO-Al 97/01907 discloses a self-healing optical network. Power levels are monitored. U.S. U.S. Patent No. 5,335,104 discloses a method for detecting interruptions in a WDM optical network. This is done by measuring the power of a ts received signal and comparing it with a reference voltage. An add / drop node for a bidirectional optical network is also disclosed in published international patent application WO-A1 96119884. The signals in a primary ring and a secondary ring are monitored at each downward detection of interruptions. U.S. U.S. Pat. No. 5,548,431 discloses a node for a bidirectional optical network with ring structure tubes. In each node, two wavelength modems are arranged. OBJECT OF THE INVENTION It is an object of the invention to provide an add / drop node, which is intended to be used in an optical optical network, which is reliable and inexpensive and in particular contains a minimum number of optical demultiplexers.

It is a further object of the invention to provide an add / drop node, which is particularly suitable for use in a network which has a self-healing mechanism, such as a "Flexbus" device. In a ring-type optical communication network, which uses wavelength multiplexing, the light signal is thus lost and demultiplexed by a single demultiplexer, also called a WDM unit, per direction, so that the power for each channel and direction is measured. each channel for emitting an output signal which corresponds to the input signal and consists of an arbitrary number of wavelengths. functionality in terms of thought demultiplexing and signal monitoring ng; b) the 'total fault conditions' in the previous year, which affect all receiving traffic, have been cleared. Should a WDM device become faulty, the self-healing mechanism of the 'Flexbus' concept can be used to ensure that all traffic is received from the direction served by the WDM device still operating and that traffic from the Satisfactory reception of the tracks is then maintained by the remaining WDM unit, and c) the design is more suitable for maintenance during operation, resumption and upgrades, as a WDM unit can support the receiving s. the track during the replacement of the other WDM device.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described as a non-limiting exemplary embodiment with reference to the accompanying drawings, in which fi g. 1 is a schematic view showing an optical ri berry with add / drop nodes, w fi g. 2 is a schematic view showing the structure of a prior art add / drop node with three WDM units, fi g. 3 is a schematic view showing the structure of an add / drop node with two WDM units.

DESCRIPTION OF THE PREFERRED FORM OF PUMP p: s I fi g. 3 shows an overview of an add / drop node 7 for an optical object, where the network is, for example, of that in fi g. 1 showed the battle. Add / drop node 7 i fi g. 3 has in essential parts a structure similar to the structure of the previously known node in fi g. 2 and the same reference numerals shall be used for identical or similar parts or elements. The networks are assumed to carry three wavelength channels, but of course channels can be used. Optical beams 3, 11, zo which transmit light signals to the node 7 are connected to the input terminals of preamplifier 21, 23. The optical beams 9, 5, which carry information signals in the direction away from the node, are connected to the output terminals of power or power amplifiers 25, 27. The respective preamplifiers 21, 23 have their output connections connected to input connections to the power amplifiers 25, 27, so that traction materials can pass from an input ing ber 3, 5 through the node 7 to the respective zs output nbs 9, ll in a substantially uninterrupted manner.

Traction channels, which enter the ring at the node 7, are introduced into the wavelength-multiplied light signal, which passes through the node, by means of the same device as in the previously known node according to fi g. Thus, traction channels T1, ..., T3 are converted, which are to be combined with the information flow, ie other traction channels, which are transmitted in the network and originate in the anode 7, into optical signals with applicable wavelength ranges in transmitter 17. These optical signals with different wavelengths are combined in an optical coupler or wavelength multiplexer or optical multiplexer 29, which has its input terminals connected to the output terminals of the transmitters 17. The combined signal is divided into a coupler 31, which is connected to the output terminal of the wavelength multiplexer 29, which has an effect, as which is substantially equal to the power of the other channel. These two signals with substantially equal power levels are combined with the path passing in both directions through the node 7 by means of couplers 33, 35, which are arranged in the connecting line between the output connection of a preamplifier 21, 23 and the input connection of a power amplifier 25. , 27, these couplers 33, 35 having their output terminals directly connected to the input terminals of the respective power amplifiers 25, 27.

However, the drain mechanism of the channels in the node 7 differs according to fi g. 3 from the mechanism according to fi g. Thus, the wavelength multiplexer 43 and its associated couplers 37, 39, 41 are omitted. Like the prior art design and in particular its elements for monitoring the power, a part of the WDM light signal or wavelength multiplexed signal, which arrives at the emergency 7, is connected from the east and west directions by means of drain switches 45, 47, which are connected in the connecting line between the output connection from a 21, 23 and the input connection to the associated power supply 25, 27, these drain connectors 45, 47 being directly connected to the output connection w from the respective preamplifier 21, 23. The drain couplers 45, 47 are connected to wavelength demultiplexers or WDM units 49, 51, which emit light signals at their output terminals, each of which includes only one wavelength range and a single information channel. These output terminals are connected to the input terminals of the associated optical power detectors 53, 55, which thus on their terminals: provide electrical signals which represent the effects or strengths of the channels PIW, ..., P3W; P1E, ... , P3E for the channels, which are broadcast on the network and which arrive from the west and east, respectively. These channel strengths or power levels of the individual channels are required to monitor and maintain a satisfactory transmission quality for the multiplexed signal which continues in the ring network. ao Each ua fi kltanal from the west, which has been demultiplexed by the demultiplexer 49, is then combined with the corresponding channel from the east, which is thus carried by light within the same wavelength range and has been demultiplexed by the demultiplexer 51. For this the signals are divided on each of the output terminals from each demultiplexer 49, 51 in two signals with, for example, substantially equal power level by means of couplers 61, 63, 65; 67, 69, 71, each having its input terminal connected to an output terminal of the demuliplexer 49, 51 and an output terminal connected to the input terminal of an optical power detector 53. The second output terminal is connected to a combining coupler 73, 75, 77. , wherein such a combining coupler is arranged for each single traction duct. A combining coupler 73, 75, 77 thus has one of its two input connections connected to a dividing coupler 61, 63, 65 for traffic arriving from the west, and a dividing coupler 67, 69, 71 for traffic arriving from the east. The output terminals of the combining couplers 73, 75, 77 thus carry the combined set of signals constituting the channels R1, RS, which are to be received in the emergency 7, and these connections are connected to the input terminals of optoelectric receivers 15. In these the received light signals and converts electrical signals to process the information therein and possibly send it to a user or another network.

Thus, an add / drop node is provided with the same functionality as a standard add / drop node but comprising only two WDM units and instead with an additional number of simple couplers for division into equal effects and for combining signals.

Claims (4)

509 807 6 PATENTIGZAV 1. An add / drop node for an optical meter, the node being arranged to be dry-connected to a first optical carrier carrying a WDM light signal comprising a number of WDM information channels to the node, and to a second optical carrier, carrying a WDM light signal comprising a plurality of WDM information channels from the node, the node being arranged to draw or drain in a drain coupler a portion of the light signal which enters the first stage, the signal portion being transmitted to a wavelength demultiplexer, in which wavelength demultiplexer is separated from each other and which emits a number of light signals, a light signal on each of its output connections and each signal comprising only one information channel, is characterized by! ao of dividing couplers, each of which is connected to one of the output terminals of the wavelength demultiplexer and has an output terminal connected to an optical detector, one detector being arranged for each dividing coupler and the other output terminal of a dividing coupler emitting a light signal to an optoelectric receiver. Add / drop node according to claim 1, characterized in that the node is arranged to be connected to ice with two first optical beams, each carrying a WDM light signal, these WDM light signals propagating in opposite directions and each comprising a number of WDM information channels, which enter the node, and with two. corresponding second optical beams, each carrying a WDM light signal, these WDM light signals propagating in opposite directions, so that pairs are formed by a second beam and a first beam, the beam in a pair carrying light signals of the same direction, and the WDM light signals on each other optical fi ber comprise a fl number of WDM light signals emanating from the node, a drain coupler ns being arranged for each pair and a demultiplexer being connected to each drain coupler, the coupling coupler and the optical coupler - an orer, wherein a combining coupler has one of its input terminals connected to the second output terminal of a first dividing coupler and another arm of its input terminals connected to the second output terminal of another corresponding second dividing coupler having its input terminal connected to the demultiplexer, to which the first dividing coupler is not connected. Optical fi measuring means comprising optical fi bearings, which are connected to each other next to nodes, characterized by an add / drop node according to one of claims 1 - 2, wherein the add / drop node is connected to at least one optical fi carrier in the network, which carries light in one direction to the add / drop node, and at least one optical fi ber in the network, which carries light in one direction away from the add / drop node. Optical fi measured according to claim 3, characterized in that the add / drop node is connected to two optical fis in the network, which carry light signals, which go in one direction to the add / drop node, and ss with two optical fis in the network, which carry light signals, which go in a direction away from the add / drop node.