SE521823C2 - Method and arrangement for bidirectional transmission over a common fiber - Google Patents

Abstract

The invention relates to a procedure and an arrangement for two-way transmission over a common fiber, more exact an architecture to, in a common transmission fiber, create a division of traffic channels in two-way transmission with common amplification. Traffic is routed through a connection (1) with channels with a plurality of nodes, which each has an optical amplifier (2). According to the invention, a first channel group (5) coming in in one direction at one side of each amplifier is routed to the input of the amplifier, and a second channel group (6), which is coming in in opposite direction at the other side of each amplifier, also to the input of the amplifier. The traffic from the output of the amplifier is divided so that the first channel group (5) is routed further at the other side of the amplifier (2) in one direction of the connection (1), and the second channel group (6) is routed further along the connection (1) in opposite direction. The invention can be used to increase the capacity of fiber optical links and also to effect protection switching of ring networks.

Description

521 823 'lo is doubled without the need to increase the number of amplifiers. The bidirectional traffic can also be used to protect traffic in optical ring networks by frequency-shifted channels carrying a copy of the traffic in the same fiber as the original but opposite it. Summary of the Invention The invention provides a method for bidirectional communication over a common optical fiber, wherein traffic is routed through a connection to a plurality of intermediate optical amplifiers.

According to the invention, a first channel group which enters in one direction on one side of each amplifier is led to the input of the amplifier and a second channel group which enters in the opposite direction on the other side of each amplifier is also led to the input of the amplifier. The traffic from the output of the amplifier is divided so that the first channel group is passed on on the other side of the amplifier in one direction on the connection and the second channel group is passed on on the connection in the opposite direction.

The regular traffic in each node can be frequency-shifted so that the regular traffic constitutes the first channel group while the frequency-shifted traffic constitutes the second channel group. The invention also relates to an arrangement for carrying out the method. The method and arrangement are defined in claims 1 and 5, respectively, while preferred embodiments are set out in the dependent claims.

Brief Description of the Drawings The invention will be described in detail below with reference to the accompanying drawings, of which Figure 1 is a schematic illustration of the present invention, Figure 2 shows an alternative embodiment of the invention and Figure 3 schematically shows a ring nut which may utilize the invention.

Detailed Description of Preferred Embodiments As mentioned above, the invention provides a method and arrangement for creating in a common transport fiber a division of channels in bidirectional transmission with common gain. The invention can be used in an architecture for protection switching of ring networks, where cost reasons militate against a protection based on conventional architecture.

The invention circumvents interference from optical nonlinearity of fibers in reinforced links and fiber optic networks, without the need to increase the number of fiber amplifiers.

In a variant of the invention, the disturbances are not reduced, but the bidirectional traffic can be used for protective switching in ring networks.

The basic component for realizing bidirectional communication with common amplification is a number of wavelength-selective couplers. In the simplest case, four simple broadband WDM couplers per amplifier are needed, but if FWM immunization is desired, more advanced filtering is required. This is currently expensive, but developments in, for example, MEMS (Integrated Micro Electro-Mechanical Systems) may provide new, cheaper components with the desired functionality.

As a simpler but good alternative to interleaving filters, polarizers are also proposed.

In the fully developed invention, which aims at protection switching in ring networks, traffic is reflected in a weakly frequency-shifted spectrum. Components for such a frequency shift are realizable. They are based on (crystalline) materials that interact with the optical signal, which can be shifted by an order of magnitude comparable to the brilliance shift in optical fiber.

Figure 1 schematically shows an arrangement according to the invention. Two amplifiers modified according to the invention are shown connected to a fiber link connection. The compound 1 consists of an optical fiber. Along the fiber, amplifiers 2 are placed to compensate for attenuation in the fiber. Amplifiers 2 can be traditional fiber amplifiers, eg EDFA (Erbium-Doped Fiber Amplifier) with a usable spectrum from about 1530 - 1565 nm. In order for amplifier 2 to be able to amplify the signals coming in opposite directions, a division is made so that both signals are led to This is accomplished by couplers 3, such as broadband WDM couplers.

As can be seen, a channel group 5 marked with light arrows from the right and a channel group 6 marked with dark arrows from the left. The channel groups together cover the amplifier's wavelength spectrum. The switches block one channel group but let through the other, so that both groups 5, 6 are led to the input of the amplifier 2 and are released in the respective opposite direction on the other side of the amplifier.

The functionality of the invention is as follows. l) Each amplifier 2 amplifies all wavelengths in one and the same direction. 2) Frequency spectrum is divided into two groups of wavelength channels at the output of the amplifier 2. 3) These groups are conducted in different directions along the transport fiber 1. By dividing the channels in two directions, the same number of channels can be achieved per fiber and direction. , why the capacity of the fiber can be doubled.

The groups can now be selected in different ways, depending on the desired system properties. 4.1) The channel groups are interleaved, ie combined with a certain, small spectral shift. This means that channels of oncoming traffic are offset in wavelength relative to each other. An appropriately balanced spectral shift minimizes interference due to rayleigh and brillouin propagation from oncoming channels in the transport fiber. 4.2) Each group is given the same, dense channel spacing as in amplifier 2, but is divided spectrally into two intervals, eg 1530 - 1545 and 1546 - 1565 nm, respectively, if the C-band of EDFA is used. Single channel spacing can be 0.8 nm according to ITU specification.

In other words, from a channel spectrum G with wavelengths lt in ascending order, G = M, X2, Ä3, .., 7t ,, ..,? TN these are divided in the interleaved case (4. 1) according to G1 = M, 7t3, .., 7tN_, and G2 = X2, 7L4, .., ÄN In simple division (4.2) this is done instead according to Gl = Ål, Ä2, .., 7t, _, and G2 = Äi, Ä¿ + ,, .., ÄN_ The distribution according to (4. 1) has a transmission advantage: for a given number of channels per direction, the relatively sparse distribution between wavelength channels running in the same direction gives a potentially low crosstalk because mainly F WM is reduced, or alternatively allows (4 1) more channels than (4.2). The distribution (4.2) allows simpler filters with lower selectivity to be used both at the amplifiers 2 and at the add / drop points. 5) After an initial coupler 3 closest to the output of the amplifier, the respective group is transported along the fiber link 1 and here meets the opposite, complementary group from an adjacent amplifier. At the end of the link, the group arrives at a switch that directs the group into the amplifier together with the oncoming, attenuated signal. This process is repeated a number of times in several fiber links, while channels from the group one by one are dropped at some drop point and replaced with new traffic channels with the same wavelength.

In the variant (4.1) - and with some limitation (4.2) - the invention provides the condition that, without increasing the number of amplifiers, it is possible to enable protective switching of traffic between all nodes in a ring network consisting of a single fiber. The functionality then gets the addition that 6) The whole spectrum with all ordinary channels is frequency shifted, approximately with twice the frequency relative to the brilliance shift of optical fiber (which is about 11 GHz), with the help of the energy supplement from phonons generated in the previously mentioned component.

This spectrum contains a copy of the information of ordinary traffic which thus gives complete redundancy if the signal could be reproduced "on the other side of the interruption". This can be done by returning the signal in a ring all the way between the nodes bordering the interruption. , i.e. the returning signal, will consist of a slightly frequency-shifted copy of ordinary traffic, this copy may constitute protected traffic in a network protected by means of the invention.

An interleaved division can cause problems with wavelength selectivity, for example when a large number of filters must be passed in the ring network. By replacing the intended multichannel filter above with (four) polarizers 4, as shown in Figure 2, this problem is avoided, since all wavelengths (with the correct polarization) can pass the polarizers 4. A polarizer is also easier to build than a multi-channel filter. Incidentally, the principle is similar.

The "misdirected" signal that reaches the output of an amplifier 2 does not pose a problem as the assumed amplifier type normally contains a built-in insulator.

It is also kept in mind that the signal power into the amplifiers is considerably less than the power at the output of the amplifiers. With the location of the polarizers near the amplifier 2, a polarization-preserving fiber is not required in the links between the amplifiers, only that the polarization of the respective signals is preserved in the amplifier 2. The attenuation in the optical track originates from four couplers (4 X 3 dB) ideally). This gives a total of about 15 dB, which is compensated by amplifier 2, but which gives increased ASE noise, Ampli fi ed Spontaneus Emíssíon, at higher amplification.

Additional noise can occur as the detector window may need to be increased.

The object of the present invention is to deflect polarized light from one direction and combine this with other incoming polarized light from another direction (eg channel group 5). To explain how the polarizers work, they are denoted by a letter A, B, C and D, respectively. A first channel group 5 is passed through in a polarizer D to the input of the amplifier 2 and a second channel group 6 is passed through through a polarizer A to the input of the amplifier 2. The combined channel groups 5 and 6 are amplified in the amplifier 2. After the amplifier 2, the channel groups 5 and 6 are separated so that they can be transmitted in different directions. This means that the first channel group 5 is passed through in polarizer B and the second channel group 6 is passed through polarizer C. Channel group 6 is blocked by polarizer C and channel group 5 is blocked by polarizer B. The above principles apply regardless of whether the wavelengths are the same in both directions or not.

Figure 3 shows the intended application of the invention as protection of the traffic in an optically amplified ring during cable excavation, anchoring, etc. Figure 3 shows how the protection is applied in a network with ten add / drop nodes 9 (smaller arrows) and intermediate transport links with a number (not shown) amplifiers each. The outer track 8 is the road for ordinary traffic, and the inner track 7 is the opposite road for protected traffic. Both tracks run in the same fiber. The protected counterclockwise traffic consists of a slightly frequency-shifted reflection (larger arrows) of all clockwise traffic in the node closest to the fiber break 10.

The larger arrows show that the protected traffic (copy) can be routed without deviations to the same point that would normally be passed by the ordinary traffic (the original). The traffic has only taken a detour around the site of the traffic offense.

The principle of the invention can be applied when upgrading existing links and networks, to increase the transport capacity (number of channels) or increased network functionality (protection). The application of the invention does not create a conflict with current ITU standards (International Telecommunications Union) as the signal lasers may have standard frequencies. However, the detectors' filters must be broadband enough to accept both ordinary and mirrored (protected) traffic.

With the invention, the protection of rings can be realized in a new way: the protected traffic may share both a common fiber and all line amplifiers with the normal traffic.

Upgrading of an existing optically amplified fiber network can be done without installing new fiber, and in some cases without changing the amplifiers. The physical change consists of a number of components that are connected to the amplifier's input and output.

Claims (9)

10 15 20 25 30 35, 521 823: L PATENTKRAV A method for bidirectional communication over a common optical fiber, wherein traffic is routed through a connection (1) with a number of nodes each comprising an optical amplifier (2), and a first channel group (5) incoming in a direction on one side of each amplifier (2) is led to the input of the amplifier (2), and a second channel group (6) entering in the opposite direction on the other side of each amplifier (2) is also led to the input of the amplifier (2); wherein the traffic from the output of the amplifier (2) is divided so that the first channel group (5) is passed on on the other side of the amplifier (2) in a direction on the connection (1) and the second channel group (6) is passed on on the connection (1) in opposite direction, characterized in that the first channel group (5) is transmitted polarized in a first polarization direction while the second channel group (6) is transmitted polarized in a second polarization direction, so that the division of channels to and from the amplifier (2) can take place by means of polarizers (4 ). Method according to claim 1, characterized in that the ordinary traffic in each node (9) is frequency-shifted, and that the ordinary traffic constitutes the first channel group while the frequency-shifted traffic constitutes the second channel group. Method according to claim 1 or 2, characterized in that the first channel group is interleaved with the second channel group. Method according to claim 1 or 2, characterized in that the first and second channel groups lie in separate frequency ranges. Arrangement for bidirectional communication over a common optical fiber, wherein traffic is routed through a connection (1) with a number of nodes, each of which comprises an optical amplifier (2), comprising: couplers (3, 4) at the input of the amplifier (2) for leading a first channel group (5) incoming in one direction on one side of each amplifier (2) to the input of the amplifier (2), and guiding a second channel group (6) incoming in the opposite direction on the other side of each amplifier (2) also to the input of the amplifier (2); coupler (3, 4) at the output of the amplifier (2) to divide the traffic so that the first channel group (5) is routed on the other side of the amplifier (2) in a direction of the connection (1) and the second channel group (6) is routed furthermore the connection (1) in the opposite direction, characterized in that the couplers (3,4) consist of polarizers (4) for separating the first channel group (5) polarized in a first polarization direction and the second channel group (6) polarized in a second polarization direction . 10 521 823 e? Arrangement according to claim 5, characterized by a device for frequency-shifting the ordinary traffic in each node (9), so that the ordinary traffic constitutes the first channel group while the frequency-shifted traffic constitutes the second channel group. Arrangement according to claim 6, characterized in that at least a part of the connection is arranged in a ring (7, 8), wherein the frequency-shifted traffic constitutes protected traffic. Arrangement according to one of Claims 5 to 7, characterized in that the first channel group is interleaved with the second channel group. Arrangement according to one of Claims 5 to 7, characterized in that the first and second channel groups are in separate frequency ranges.