GB2283884A - Add/drop multiplexer apparatus - Google Patents

Abstract

A communications network, having an SDH transmission line 2a to 2e with for example four main channels #1, #2, #3, #4, is provided at four different tributary connection nodes nodes 1 to 4 with respective add/drop multiplexer units 1a to 1d for permitting interchange of information signals between the main channels #1, #2, #3, #4 and tributary channels 6a to 6h the network connected to respective tributary ports A to H. Each add/drop multiplexer unit includes a time slot interchange unit 10a to 10d through which a pair of the main channels pass but which the other two main channels bypass. Because different pairs of the main channels pass through the different time slot interchange units, signal interchange is possible between any one of the main channels and any one of the tributary channels. The add/drop multiplexer units can be located together at a single node, if required. Alternatively, they can be formed into an Optical ring network as shown in Figure 10. <IMAGE>

Description

ADD/DROP KULTIPLEXgR APPARATUS The present invention relates to add/drop multiplexer apparatus for use, for example, in synchronous digital hierarchy (SDH) communications networks to connect tributary channels of the network to main channels thereof.

Figure 1 of the accompanying drawings shows one example of an STM-4 add/drop multiplexer (ADM) previously considered for use in an SDH network. An optical transmission line 2, for example an optical ring, carrying a synchronous transport module at level 2 of the SDH hierarchy (STM-4), passes through the ADM 1. The bit rate of the STM-4 module is 622.08Mbit/s (hereinafter 622Mbit/s).

Each STM-4 module carries four SDH level 1 (STM-1) modules in time-division multiplexed form. These four STM-1 modules can be regarded as providing the transmission line 2 with four separate 155.52Mbit/s (hereinafter 155Mbit/s) main channels extending in parallel. Each STM-1 module (main channel) can be used to transport a plurality of individual lower-bit-rate information signals (tributary signals), and Figure 2 of the accompanying drawings shows one example of the structure of an STM-1 module used to transport up to 63 2.048Mbit/s (hereinafter 2Mbit/s) tributary signals.

As shown in Figure 2, each 2Mbit/s tributary signal to be transported within an STM-1 module is incorporated in a container C-12. A path overhead (POH) is added to the container to form a virtual container VC-12. This path overhead (POH) contains information identifying the tributary signal concerned, error checking information, and information identifying the type of container (in this case 2Mbit/s) involved.

Each virtual container VC-12, has, associated therewith, a pointer indicating the start point of the virtual container VC-12 concerned in its STM-1 frame, the virtual container and its pointer together forming a tributary unit TU-12. Thus, the containers C-12 are the respective payloads of the tributary units TU-12.

In Figure 2, the 63 tributary units TU-12 which can be accommodated within an STM-1 module are combined in groups of 3 to form twenty-one tributary-unit groups TUG-2. These groups are then further combined, by bit interleaving and addition of path overheads (POH), to form a higher-order virtual container VC-4 which is located within the module by means of a further pointer. The higher-order virtual container VC-4 and its associated pointer constitute an administrative unit (AU). In the example shown in Figure 2, the administrative unit AU-4 forms the entire payload of the module STM-1, the module only further including section overhead (SOH) required for transmission purposes.

Further information on SDH networks can be found, for example, in "The New CCITT Synchronous Digital Hierarchy: Introduction and Overview", Harrison K.R., British Telecommunications Engineering, Vol. 10, July 1991, page 104, and in ITU-T Recommendations G.707 (Synchronous Digital Hierarchy Bit Rates), G.708 (Network Node Interfaces for the Synchronous Digital Hierarchy) and G.709 (Synchronous Multiplexing Structure).

Returning now to Figure 1, in the ADM 1 first and second VC-4 time slot assignment units (TSA) 3a and 3b are provided at the interfaces of the ADM with respective left-hand and right-hand portions 2a and 2b of the optical transmission line 2. These TSAs 3a and 3b are multiplexers/demultiplexers (muldems) and signal distributors which serve to provide access to the four higher-order virtual containers VC-4 in an STM-4 module; thus, the TSA 3a serves to provide access to the four VC-4s in the STM-4 module carried by the left hand transmission line portion 2a, and the TSA 3b serves to provide access to the four VC-4s in the right-hand transmission line portion 2b.

The ADM 1 is also connected, via respective interface units 5a, Sb and Sc thereof, to three tributary channels 6a, 6b and 6c, each of which can carry an STM-1 module or a single 140Mbit/s, 45Mbit/s or 34Mbit/s tributary signal or up to twenty-one 2Mbit/s tributary signals.

The ADM 1 further includes a time slot interchange unit (TSI) 10 which has six ports P1 to P6. The first port P1 of the TSI 10 is connected via the TSA 3a to access a first higher-order virtual container VC-4&num;1 of the transmission line portion 2a. The second and third ports P2 and P3 of the TSI 10 are connected via the interface units 5b and Sc to access respectively the tributary signals of the tributary channels 6b and 6c.

The fourth port P4 of the TSI is unused in this example.

The fifth and sixth ports P5 and P6 are connected via the TSA 3b to access respectively first and second higher-order virtual containers VC-4&num;1 and VC-4&num;2 of the transmission line portion 2b.

The interface unit 5a is connected to access a second higher-order virtual container VC-4&num;2 of the transmission line portion 2a, and the third and fourth higher-order virtual containers VC-4&num;3 and VC-4&num;4 of the transmission line portion 2a are connected respectively to the corresponding third and fourth higher-order virtual containers VC-4&num;3 and VC-44 of the transmission line portion 2b.

The TSI 10 is essentially a patch panel provided between two multiplexers/demultiplexers, and in use of the ADM 1 serves to permit any virtual container in a channel connected to one of its ports to be added to or dropped from another channel connected to another of its ports.

Ideally, in the example shown in Figure 1, the TSI 10 would enable any VC-12 in any of the tributary channels to be added to/dropped from any of the VC-4s in the transmission line 2. However, this would require the TSI to have access to all four VC-4s in each transmission line portion 2a or 2b, and also access to all the tributary signals. In turn, this would require the TSI to have eleven ports, and, because each VC-4 can contain up to sixty-three VC-12s, a capability of interchanging 693 (= 11 x 63) VC-12s.

However, the number of electronic circuitry gates required to provide a time slot interchange unit having such a virtual container interchange capability is prohibitively high and, even if technically feasible, the cost cannot always be justified at each tributary connection node (add/drop location) of a network.

Presently, a TSI having six ports and a maximum virtual container interchange capability of 378 (= 6 x 63) VC-12s is contemplated. This falls far short of the desired virtual container interchange capability mentioned above and leads to system design limitations such as, for example in Figure 1, the inability to add VC-12s of the tributary channels 6b and 6c to the third and fourth VC-4s VC-4*3 and VC-4&num;4 of either transmission line portion 2a or 2b. In addition, there is no continuity between the second VC4 of the transmission line portion 2a and the second VC-4 of the transmission line portion 2b so that effectively one of the four main channels of the transmission line 2 is broken at the ADM 1; in Figure 1 all VC-12s of the tributary channel 6a are passed by the TSA 3a to the second VC-4 of the transmission line portion 2a.

In view of the limited capabilities of present time slot interchange units, alternative ways have been proposed of realising a 2-622Mbit/s ADM capable of adding/dropping 2Mbit/s signals to/from any of the VC 4s in an STM-4 module.

In one such proposal, illustrated in Figure 3 of the accompanying drawings, access to the individual 2Mbit/s signals in all four VC-4s in each transmission line portion 2a or 2b is achieved by providing a 155-622Mbit/s add/drop line terminal 50 and four 2 155Mbit/s add/drop line terminals 60 at each transmission line interface. The proposal also uses a 2Mbit/s patch panel 70 having ports for connection to all the accessed 2Mbit/s signals of the VC-4s of the two transmission line portions 2a and 2b, and also has further ports for adding/dropping 2Mbit/s tributary signals.

This arrangement is disadvantageous, however, since it uses a relatively large amount of hardware.

Also, because it makes use of STM-4 and STM-1 line terminal equipment, the SDH signals are terminated at the 2Mbit/s interfaces between the add/drop line terminals 60 and the patch panel 70 so that end-to-end path monitoring capability is lost.

A further proposal, shown in Figure 4 of the accompanying drawings, uses a VC-4 time slot assignment unit 80 and a VC-12 time slot assignment unit 90 at each transmission line interface to provide access to all the VC-12s carried by the STM-4 modules in each transmission line portion 2a or 2b. A VC-12 crossconnect unit 100 has ports connected to all the accessed VC-12s and also further ports for adding/dropping VC-12s to/from tributary channels. The disadvantage of this proposal is that the switch matrix required is complex and requires sophisticated control.

According to the present invention there is provided add/drop multiplexer apparatus, for connection to main channels and a tributary channel of a communications network, including a first signal interchange unit, through which a first such main channel passes when the apparatus is in use, having a tributary port for connection to such a tributary channel, which unit is operable to cause an information signal to pass between a first such main channel and that tributary channel when the apparatus is in use, and the apparatus also including a second signal interchange unit, through which the said first main channel and a second such main channel pass when the apparatus is in use, operable to cause the said information signal to pass between the first and second main channels, thereby enabling such an information signal to be transferred between the said tributary channel and the said second main channel.

Such apparatus can enable the transfer of an information signal between the tributary channel connected to the first signal interchange unit and the second main channel of the network, even though that interchange unit does not itself provide access to the second main channel. As a result the signal interchange capability of each signal interchange unit can be reduced from that which would be required by a single signal interchange unit used to facilitate interchange of an information signal between the tributary channel and either one of the first and second main channels.

Preferably the said second signal interchange unit also has a tributary port for connection to a further such tributary channel and is operable to cause the said information signal to pass between the said first main channel and that further tributary channel. This can enable transfer of an information signal between the respective tributary channels of the first and second signal interchange units.

A third signal interchange unit may be used, through which the said second main channel and a third such main channel pass, which unit is operable to cause an information signal to pass between the second and third main channels. In this case, it is preferable that the said third main channel also passes through the said first signal interchange unit, that unit being operable to cause such an information signal to pass between its said tributary channel and the said third main channel. In this way, an information signal can pass, via the third main channel, between the tributary channel of the first signal interchange unit and the second main channel, whilst another information signal passes between the tributary channel of the second interchange unit and the first main channel, even though the first signal interchange unit itself provides no access to the second main channel.

Furthermore, because in this arrangement each main channel passes through only two out of the three signal interchange units (the second main channel bypasses the first signal interchange unit, the third main channel bypasses the second signal interchange unit, and the first main channel bypasses the third signal interchange unit) the series connection of the three signal interchange units imposes less end-to-end delay on signals carried by the main channels than if all three main channels passed through each signal interchange unit.

For full connection versatility it is preferable that there are as many signal interchange units in total as there are main channels of the network. The units are connected to the main channels in a cyclic fashion such that a different pair of the main channels passes through each of the units. When the communications network is a ring network having four main channels, it is preferable that there are (8 + 4n) such signal interchange units, where n is zero or a positive integer, arranged at respective connection nodes around the ring network. When the traffic distribution around the ring network is uniform this can enable the bandwidth utillsation to be equal to that which can be achieved using a full cross-connect capability at each node.

The communications network is, for example, a synchronous digital hierarchy network the said main channels of which are provided by respective higherorder virtual containers, for example virtual containers VC-4s, and the said information signals are transported through the network in respective lowerorder virtual containers, for example virtual containers VC-lls or VC-12s. Each VC-4 can transport up to 63 VC-12s.

In one embodiment, which can provide a distributed add/drop multiplexer, a series of individual add/drop multiplexer devices are arranged in series at different respective connection nodes along a transmission line of the communications network, this transmission line providing the said main channels of the network between adjacent devices of the series. Each device includes one of the said signal interchange units and two muldem units, connected respectively to the two sides of the said transmission line at the connection node concerned and also connected within the device to one another and to the signal interchange unit of the device. The muldem units serve to provide access to the individual main channels of the transmission line on each of the said two sides thereof and also serve to connect two of the accessed main channels of one side and the corresponding two accessed main channels of the other side to the signal interchange unit of the device, whilst connecting the remaining accessed main channel(s) of the said one side directly to the corresponding accessed main channel(s) of the said other side. Such an embodiment is cost-effective because it can make use of signal interchange units having a relatively low signal interchange capability at each node. Also, it is usual for the tributary channels of a network to be distributed along the transmission line so that some form of distributed add/drop multiplexing facility is normally required.

When such distributed add/drop multiplexer apparatus is used in a ring network in which the traffic distribution is hubbed rather than uniform, an add/drop multiplexer device at the hub connection node preferably includes two of the said signal interchange units and two muldem units connected respectively to the two sides of the said transmission line at the hub connection node and also connected within the device to the two signal interchange units of the device.The muldem units serve to provide access to the individual main channels of the transmission line on each of the said two sides thereof and also serve to connect two of the accessed main channels of one side and the corresponding two accessed main channels of the other side to one of the said two signal interchange units of the device and to connect the remaining accessed main channel(s) of the said one side and the corresponding accessed main channel(s) of the said other side to the other of the said two signal interchange units of the device, so that at the hub connection node there is access to all of the main channels of the transmission line.

Alternatively, the said signal interchange units may be connected together in series within a single add/drop multiplexer device arranged at a connection node along a transmission line used to provide the main channels. In this case, the device need include only two muldem units connected respectively to the two sides of the said transmission line at the said connection node and also connected respectively to the first and last signal interchange units of the said series, which muldem units serve to provide access to the individual main channels of the transmission line on each of the said two sides thereof. The main channels need not be multiplexed between each pair of adjacent signal interchange units of the series and can pass along respective channel connection lines of the device, so avoiding the need for muldems between each pair.

The above-mentioned transmission line can be a higher-rate synchronous digital hierarchy transmission line STM-N, for example an STM-4 (622Mbit/s) or STM-16 (2488.32Mbit/s) line.

Reference will now be made, by way of example, to the accompanying drawings, in which: Figure 1, discussed hereinbefore, is a block diagram of an example of a previously-considered STM-4 add/drop multiplexer; Figure 2, also discussed hereinbefore, is a diagram for use in explaining a data transport structure used in a synchronous transport module of a synchronous digital hierarchy communications network; Figures 3 and 4, also discussed hereinbefore, are respective block diagrams of further previouslyconsidered STM-4 add/drop multiplexers; Figures SA to 5D are respective block diagrams of add/drop multiplexer units for use in explaining a principle of the present invention;; Figure 6 is a block diagram showing the four add/drop multiplexer units of Figure 5A to 5D connected together to form a distributed add/drop multiplexer embodying the present invention; Figure 7 is a block diagram of another add/drop multiplexer embodying the present invention; Figures 8 and 9 are respective block diagrams of add/drop multiplexer units for use in further add/drop multiplexers embodying the present invention; Figure 10 is a schematic view of an optical ring network employing add/drop multiplexers embodying the present invention; Figure 11 is a diagram illustrating connections provided by the Figure 10 ring network; Figure 12 is a graph illustrating the relationship between bandwidth utilisation and the number of nodes in the Figure 10 ring network;; Figure 13 shows a table presenting an example of the traffic distribution in the Figure 10 ring network; and Figure 14 is a block diagram of another add/drop multiplexer embodying the present invention for use at a hub connection node of a ring network.

The add/drop multiplexer unit la of Figure 5A is arranged at a first tributary connection node (node 1) of an STM-4 transmission line 2 of an SDH network, which line is used for carrying an STM-4 synchronous transport module. As explained previously, this STM-4 module in fact comprises four STM-1 synchronous transport modules multiplexed together, and each STM-1 module carries a higher-order virtual container VC-4 having a data capacity of up to 63 2Mbit/s information signals. The higher-order virtual containers VC-4s can be regarded as providing respective main channels of the transmission line 2.

The unit la of Figure 5A has the same basic constitution as the add/drop multiplexer shown in Figure 1, and includes a first time slot assignment unit (TSA) 3a connected to a first portion 2a of the SDH transmission line 2, a second TSA 3b connected to a second transmission line portion 2b, first and second interface units 5a and 5b connected to respective tributary channels 6a and 6b of the network, and a first time slot interchange unit (TSI) 10a.

As shown in Figure 5A, the information signals carried by the tributary channels 6a, 6b can be plesiochronous digital hierarchy (PDH) signals, in this example 21 2.048Mbit/s PDH signals multiplexed together or a single 34Mbit/s PDH signal, or synchronous digital hierarchy (SDH) signals, in this example a single STM-1 SDH signal.

For the purposes of explanation, it will be assumed hereinafter that the node 1 tributary channels 6a and 6b (and also the tributary channels at all the other tributary connection nodes to be described later with reference to Figures 5B to 5D) are all single STM1 SDH channels, each STM-1 channel carrying up to 63 2Mbit/s information signals in respective virtual containers VC-12. However, as will be understood, the tributary channels need not all be of the same type, and PDH and SDH information signals can be mixed between different nodes and even between the two different tributary channels at the same node.

In the case of non-SDH tributary signals, the interface units 5a and 5b serve as necessary to produce from non-SDH information signals in the tributary channels suitable SDH virtual containers, e.g. VC-12s from 2Mbit/s PDH information signals, for addition to the main channels (higher-order virtual containers VC4s) of the transmission line 2. Similarly, virtual containers VC-12s carried by the transmission line 2 that are to be dropped to a non-SDH tributary channel are converted to the appropriate non-SDH information signal, e.g. virtual containers VC-12 are converted into 2Mbit/s PDH information signals, as they pass through the interface units 5a and 5b into the tributary channels 6a and 6b.

In Figure 5A, the time slot interchange unit 10a of the unit la has six ports P1 to P6. These ports are, however, connected differently from the ports of the time slot interchange unit 10 in the exemplary ADM shown in Figure 1. In particular, the ports P1, P2, P5 and P6 are connected via the TSAs 3a and 3b to provide the TSI 10a at the first tributary connection node with access to the first and second main channels of the transmission line 2, i.e. the TSI 10a has access to the first and second VC-4s VC-4&num;1 and VC-4&num;2 of the respective STM-4 modules carried by the first and second transmission line portions 2a and 2b. The remaining two ports P3 and P4 of the TSI 10a are connected via the interface units 5a and 5b to the tributary channels 6a and 6b.The third and fourth VC4s VC-4&num;3 and VC-4&num;4 of the STM-4 modules carried by the transmission line portions 2a and 2b pass directly between the TSAs 3a and 3b, so that the TSI 10a does not have access to the third or fourth main channels of the transmission line 2.

By virtue of the connection arrangement shown in Figure 5A, all four main channels (VC-4s) of the transmission line 2 pass through the add/drop multiplexer unit la, and virtual containers VC-12 of the tributary channels 6a and 6b can be added to or dropped from the first and second main channels (VC-4&num;1 and VC-4&num;2) of the transmission line 2. The TSI 10a need have a virtual container interchange capability of only 378 (=6 x 63) VC-12s.

At a second tributary connection node (node 2) along the transmission line 2, a second add/drop multiplexer unit 1b is provided, this unit being connected to the first add/drop multiplexer unit la by the second portion 2b of the transmission line. The second add/drop multiplexer unit lb of Figure 5B is constituted similarly to the first add/drop multiplexer unit la of Figure 5A, and has first and second TSAs 3c and 3d, interface units Sc and 5d, and a time slot interchange unit 10b having the same time slot interchange capability (378 VC-12s) as the time slot interchange unit 10a. A third transmission line portion 2c is connected to the second TSA 3d, and respective tributary channels 6c and 6d are connected to the interface units Sc and 5d.

In the add/drop multiplexer unit lb of Figure SB, however, the connection arrangement is different from that used in the add/drop multiplexer unit la of Figure 5A. In the add/drop multiplexer unit lb, the second and third main channels (VC-4&num;2 and VC-4&num;3) are routed through the TSI 10b, and the first and fourth main channels (VC-4&num;1 and VC-4&num;4) pass directly between the TSAs 3c and 3d.Because the first and second add/drop multiplexer units la and lb are connected together by the second transmission line portion 2b, if a VC-12 of one of the tributary channels 6a or 6b of node 1 is inserted by the TSI 10a at that node into the second main channel (VC-4&num;2), the inserted VC-12 will pass into the TSI 10b of the second add/drop multiplexer unit ib at node 2 and can either be dropped to one of the tributary channels 6c or 6d of node 2 or it can be passed on further to the third transmission line portion 2c via the second or third main channel (VC-4&num;2 or VC-4&num;3).Thus, although a VC-12 from the node 1 tributary channels 6a and 6b could not be inserted at node 1 into the third main channel (VC-4&num;3) of the transmission line 2, because that third main channel does not pass through the TSI 10a of the add/drop multiplexer unit la at node 1, the use of the two add/drop multiplexer units la and lb connected together can enable such a virtual container from the node 1 tributary channels to reach the third main channel (VC4&num;3).

To provide further versatility, a third add/drop multiplexer unit lc, as shown in Figure 5C, can be provided at a third tributary connection node (node 3) along the transmission line 2. In the third add/drop multiplexer unit ic the third and fourth main channels (VC-4&num;3 and VC-4&num;4) pass through the TSI 10c, whilst the first and second main channels pass directly between the TSAs 3e and 3f.Accordingly a virtual container VC-12 of one of the node 1 tributary channels 6a or 6b can reach the fourth main channel (VC-4&num;4) of the transmission line 2 at node 3, having been added to the second main channel (VC-4&num;2) by the TSI 10a in the add/drop multiplexer unit la of node 1, passed into the third main channel (VC-4&num;3) by the TSI 10b in-the add/drop multiplexer unit 1b of node 2, and then finally passed into the fourth main channel by the TSI 10c in the add/drop multiplexer unit Ic of node 3.

Alternatively, the added VC-12 can be dropped from the third main channel (VC-4&num;3) to one of the tributary channels 6e or 6f at node 3.

The addition, at a fourth tributary connection node (node 4) along the transmission line 2, of a fourth add/drop multiplexer unit ld, in which the first and fourth main channels (VC-4&num;2 and VC-4&num;3) pass through the TSI 10d and the second and third main channels pass directly between the TSAs 3g and 3h, provides full versatility of interconnection. Thus, for example, a virtual container VC-12 of one of the node 1 tributary channels 6a or 6b, added into the first main channel (VC-4&num;1) at node 1, can reach the fourth main channel via the TSI 10d in the add/drop multiplexer unit id of node 4.

When there are as many add/drop multiplexer units as there are main channels, any tributary channel virtual container can be added to or dropped from any of the main channels, by virtue of the "cyclic manner" in which the TSI of the series of add/drop multiplexer units are connected.

Figure 6 shows the four add/drop multiplexer units la to 1d of Figures 5A to 5D connected together to form a distributed 2-622Mbit/s add/drop multiplexer. This distributed multiplexer has two tributary ports A, B; C, D; E, F; and G, H at each node 1 to 4, and tributary signals input to the tributary ports at any one node can be directed to the tributary ports of any other node even though at each node there is access to only two main channels of the transmission line 2.

For example, consider a 2Mbit/s tributary signal applied at tributary port A which it is required to drop at tributary port F. The add/drop multiplexer unit la at node 1 provides access to the first and second main channels (VC-4&num;1 and VC-4&num;2) but the add/drop multiplexer unit lc at node 3 only provides access to the third and fourth main channels (VC-4&num;3 and VC-44). Thus, the VC-12 associated with the applied 2Mbit/s tributary signal should be inserted into the second main channel (VC-4&num;2) by the TSI 10a at node 1. At node 2, this VC-12 should be transferred to the third main channel (VC-4&num;3) by the TSI lob at that node. When the VC-12 arrives at node 3 it will therefore be in a main channel (VC-4), in this case the third main channel (VC-4&num;3), which is connected to the TSI 10c of this node, and hence the VC-12 concerned can be dropped to the tributary port F.

The routing of the virtual containers can be accomplished via the usual control facilities available in the processing cards of an add/drop multiplexer unit.

It will be seen that a distributed 2-622Mbit/s multiplexer as shown in Figure 6 has the advantage that the equipment at each node is simpler, and hence cheaper, than would be the case if at each node there was provided a 2-622Mbit/s multiplexer which had sufficient processing to enable all main channels (VC4s) in the STM-4 transmission line to be accessed.

Furthermore, as interchange of the VC-12s does not occur at each node through which a VC-12 passes, the end-t6-end delay will be less than an equivalent system in which VC-12 interchange occurred in each node.

Although Figure 6 shows a distributed 2-622Mbit/s add/drop multiplexer, it will be appreciated that in other embodiments of the present invention it is possible for a series of add/drop multiplexer units to be located at the same node on a transmission line, to form a single piece of equipment, as shown in Figure 7.

The Figure 7 equipment comprises the four TSIs 10a to 10d connected together in the "cyclic manner" described above with reference to Figures 5A to 5D and 6, but the interfaces between adjacent TSIs within the equipment can be provided in each case by four electrical signal lines carrying respective higher-order virtual containers VC-4s. Accordingly, the Figure 7 equipment needs only two time slot assignment (TSA) units 3a and 3b to serve as electrical/optical interface units for generating the optical STM-4 signals for transmission along the transmission line 2. Thus, the Figure 7 equipment can be considerably smaller than a series of four optically-connected add/drop multiplexer units la to Id.

It will also be seen that, as in the distributed multiplexer of Figure 6, the Figure 7 equipment permits up to 63 2Mbit/s signals to be dropped/inserted from/to any main channel (VC-4) in an STM-4 transmission line, whilst being simpler than the previous proposals described above with reference to Figures 3 and 4.

The main channels of the transmission line can be provided by a single physical line, as described above, or by separate respective physical lines if desired.

Rather than time-division multiplexing (TDM), wavelength-division multiplexing (WDM) can be used to enable several optical signals, having different respective wavelengths, to pass along a single optical transmission line. For example, instead of the timedivision multiplexed STM-4 optical transmission line 2 described previously, as shown in Figure 8 it would be possible to use a wavelength division-multiplexed optical transmission line 102 carrying 4 STM-1 optical signals at different respective wavelengths X1 to X4.

In this case, at each interface with a transmission line portion 102a or 102b, in place of the time slot assignment units TSA 3a and 3b of Figure 8 (which each have an STM-4 optical port on the transmission line side and four STM-1 electrical ports on the TSI side), there are provided VC-4 TSA units 103a and 103b having 4 STM-1 electrical ports on each side. The four ports on the line side of the TSA unit 103a or 103b are connected to respective ports of an optical transceiver 107a or 107b which converts the four STM-1 electrical signals to respective STM-1 optical signals having the wavelengths X1 to X4, and vice versa. In the outgoing direction the STM-1 optical signals are multiplexed together by a wavelength muldem 108a or 108b to produce a wavelength-division multiplexed optical aggregate signal.In the incoming direction, the wavelengthdivision multiplexed optical aggregate signal carried by the transmission line 102 is demultiplexed by the muldem 108a or 108b into its four constituent STM-1 optical signals at the different wavelengths X1 to A4.

The add/drop multiplexer unit 101 of Figure 8 has its TSI 110 connected in the same manner as the TSI 10a of the add/drop multiplexer unit la of Figure 5A. As will be appreciated, by employing further such add/drop multiplexer units 101 at respective further tributary connection nodes along the transmission line 102, with different pairs of the main channels passing through the respective TSIs of the different units 111 (as in Figures 5A to 5D), it becomes possible to interchange signals between the tributary channels and three or all four of the main channels, even through each TSI itself has insufficient capacity to afford access to all the main channels at its tributary connection node.

In a further embodiment, instead of employing wavelength-division multiplexing, it would be possible to use the 4 STM-1 electrical signals on the line side of each VC-4 TSA unit 103a or 103b to modulate respective sub-carrier signals, and to combine the four modulated sub-carrier signals to produce a composite electrical signal, which is then being converted to an optical signal for transmission via the transmission line. Such a multiplexing technique is relatively inefficient, however, in terms of use of the available transmission line bandwidth.

Although the present invention has been described hereinbefore in the context of an SDH transmission line, it will be appreciated that embodiments of the present invention are applicable to provide connections between tributary channels and main channels of other types of communications network such as SONET (synchronous optical networks) networks and PDH (plesiochronous digital networks) networks.

For example, as shown in Figure 9, an add/drop multiplexer unit 111, for use at a tributary connection node of a PDH optical transmission line 112, has the same basic configuration as the add/drop multiplexer units la to id of Figures 5A to 5D. In the example shown the transmission line 112 carries a PDH signal which consists of 4 140Mbit/s individual PDH signals multiplexed together. These l40Mbit/s PDH signals constitute respectively the main channels of the PDH transmission line 112.

The unit 111 includes first and second combined optical transceiver and electrical muldem units 113a and 113b for providing access to the individual 140Mbit/s PDH signals (main channels) in the transmission line portions 112a and 112b, and first and second interface units 11Sa and 115b connected to respective tributary channels 116a and 116b. In this case, the tributary channels connected to each interface unit can be n 2Mbit/s PDH signals (n s 64, typically n = 16) or a single 34Mbit/s PDH signal, or a single 140Mbit/s PDH signal.

The unit 111 also includes a time slot interchange unit (TSI) 120 which in this case contains a 2-8-34140Mbit/s muldem and a cross connection unit for 2Mbit/s signals. The muldem in the TSI 120 provides access, down to the 2Mbit/s level, to all the signals in the first and second 140Mbit/s signals (first and second main channels) carried by the transmission line 112, and, if required, to all the signals in the tributary channels 116a and 116b.

The cross connection unit in the TSI 120 then enables signal interchange, at the 2Mbit/s level (instead of VC-12 level as in the SDH ADM unit described hereinbefore), between the first and second main channels and the two tributary channels 116a and 116b.

The add/drop multiplexer unit 111 of Figure 9 has its TSI 120 connected in the same manner as the TSI 10a of the add/drop multiplexer unit la of Figure 5A. As will be appreciated, by employing further such add/drop multiplexer units 111 at respective further tributary connection nodes along the PDH transmission line 112, with different pairs of the main channels (140Mbit/s signals) passing through the respective TSIs of the different units 111 (as in Figures 5A to 5D), it becomes possible to interchange signals between the tributary channels and three or all four of the main channels, even through each TSI itself has insufficient capacity to afford access to all the main channels at its tributary connection node.

Figure 10 shows an example of the use of add/drop multiplexer apparatus embodying the present invention in an optical ring network. In the Figure 10 example, an optical ring network 200 with 8 nodes has an add/drop multiplexer 1 embodying the present invention at each node. The nodes are connected together by an STM-4 ring 2 made up of individual STM-4 transmission line portions 212 - 2s-1- As shown schematically in Figure 11, which illustrates the VC-4 connectivity in the case of the Figure 10 ring, this arrangement can provide access at each node to both adjacent nodes and to every fourth node in the ring. This allows traffic to be routed between any two nodes in the ring, but the maximum bandwidth utilisation depends on the traffic distribution, the chosen connectivity pattern and the number of nodes.

Firstly, bandwidth utilisation in the case in which the traffic distribution within the ring is uniform will be considered. The traffic connection matrix for node 1 of the Figure 10 eight node ring is shown in Table 1 below.

In Table 1, c12 denotes the VC-4 used to transport the traffic at node 1 destined for node 2 over link 1-2 (the transmission line portion 212); cl3 denotes the VC-4 used to transport the traffic at node 1 destined for node 3 over link 1-2; etc.

Table 1

Link 1-2 2-3 3-4 4-5 5-6 6-7 7-8 8-1 Traffic: 1-2 cl2 Traffic: 1-3 C13 C23 Traffic: 1-4 C14 C24 C34 Traffic: 1-5 c15 c25 c35 c45 Traffic: 1-6 C1 C26 C36 C46 Cs Traffic: 1-7 c17 c27 c37 c47 c57 c67 Traffic: 1-8 C18 C28 C38 C48 C58 c68 c,8 Table 2 presents a traffic distribution matrix for traffic from node 1, illustrating the distribution of traffic amongst the VC-4s for traffic sourced from node 1. In Table 2, S11 denotes the sum of the traffic allocated to VC&num;1 for link 1-2 as defined in the connection matrix of Table 1; S12 denotes the sum of the traffic allocated to VC&num;1 for link 2-3 (the transmission line portion 22-3) as defined in the Table 1 connection matrix; etc.

Table 2

Link 1-2 2-3 3-4 4-5 5-6 6-7 7-8 8-1 VC&num;1 S11 S12 S13 S14 S15 S16 S17 S18 VC&num;2 S21 S22 S23 S24 S75 S26 S27 S28 V&num;3 S31 S32 S33 S34 S35 S36 S37 S38 V&num;4 S41 S42 S43 S44 S45 S46 S47 S48 By virtue of the symmetry of the "cyclic" connectivity pattern employed in apparatus embodying the present invention, the traffic distribution matrix of Table 2 can be used to determine the total amount of traffic allocated to each VC-4, taking into account traffic from all the nodes.The results are given in Table 3, which presents a traffic distribution matrix for traffic from all nodes.

Table 3

1-2 2-3 3-4 4-5 5-6 6-7 7-8 8-1 V&num;1 T,l T,2 T,3 T14 T15 T,6 T,7 T18 VC*2 T21 T22 T23 T24 T25 T26 T2, T28 VC&num;3 T31 T32 T33 T34 T35 T36 T37 T38 VC&num;4 T41 T42 T43 T44 T45 - T46 T47 T48 where:: VC&num;1 (Link 1-2) = T11 = 11+S22+S33+S44+S15+S26+S37+S48 VC&num;2 (Link 1-2) = T21 = S21+S32+S43+S14+S25+S36+S47+S18 VC&num;3 (Link 1-2) = T31 = S31+S42+S13+S24+S35+S46+S17+S28 VC&num;4 (Link 1-2) = T41 = S41+S12+S23+S34+S45+S16+S27+S38 VC&num;1 (Link 2-3) = T12 = S12+S23+S34+S45+S16+S27+S38+S41 = T41 VC&num;2 (Link 2-3) = T22 = S22+S33+S44+S15+S26+S37+S48+S11 =T11 VC&num;3 (Link 2-3) = T32 = S32+S43+S14+S25+S36+S47+S18+S21 =T21 VC&num;4 (Link 2-3) = T42 = S42+S13+S24+S35+S46+S17+S28+S31 = T31 etc It can be seen from the above expressions that the total traffic distribution can be reduced to the form shown in Table 4.

Table 4

Link 1-2 2-3 3-4 4-5 5-6 6-7 7-8 8-1 V&num;1 T11 T41 T31 T21 T11 T41 T31 T21 VC&num;2 T,3 T11 T41 T31 | T21 T11 T41 T31 VC&num;3 T31 T21 T11 T41 T31 T21 T11 T41 VC&num;4 T, T31 T21 T11 T41 = T31 = T21 T11 The maximum bandwidth utilisation is obtained when each VC-4 transports 63 x 2Mbit/s information signals, so that for example:: T11 = T21 = T31 = T41 = 63 x 2Mbit/s If the traffic cannot be distributed equally between the VC-4s, then the traffic between the nodes must be reduced so that the maximum traffic carried by one VC-4 is 63 x 2Mbit/s.

The bandwidth utilisation (BU) is given by: BU = (Tll+T2l+T3l+T4l)/(252 X 2Mbit/s) where Tij is at maximum 63 x 2Mbit/s.

Figure 12 shows a graph illustrating the variation of the bandwidth utilisation (BU) according to the number of nodes in the ring. As seen from Figure 12, with four nodes the bandwidth utilisation is limited to 50%, but with only eight nodes the utilisation of ring capacity can be equal to that which can be achieved using a full cross-connect capability at each node. In general, it is possible to achieve 100k bandwidth utilisation for rings with (8 + 4n) nodes, where n is zero or a positive integer.

The significance of this result is that by using the "cyclic" connectivity approach according to the present invention, the same performance can be achieved as for a ring which has sufficient capacity at each node to cross-connect all the VC-12s in the aggregate line signal, but this is achieved with only 60% of the number of switch ports and as little as 36% of the switch circuitry (depending on the switch architecture) at each node.

The "cyclic" connectivity approach has the additional advantage that not all of the traffic passes through the TSI unit at every node and so the end-toend delay is reduced.

Figure 13 presents a concrete example of the VC-4 connectivity in the case of an 8 node ring. The figures in the individual boxes in the Table of Figure 13 each represent the number of 2Mbit/s channels in the link or virtual container concerned.

Bandwidth utilisation in the case in which the traffic distribution is non-uniform will now be considered. The cyclic connectivity approach according to the present invention can be applied to a network having a hub traffic distribution. In this case, however, it is necessary to access all four VC-4s at the hub node. This can be achieved by using a modified add/drop multiplexer 1H at the hub node, as shown in Figure 14. This ADM 1H includes two TSI units 10a and 10b, the first TSI unit 10a being connected to access VC-4&num;1 and &num;2 from both the STM-transmission line portions 2a and 2b connected to the hub node, and the second TSI unit 10b being connected to access VC-4&num;3 and &num;4 from the line portions 2a and 2b. A single TSI unit is used at all other nodes in the ring.

With this arrangement it is possible to achieve 100% bandwidth utilisation for a ring with any number of nodes.

In an add/drop multiplexer embodying the present invention, there can be any appropriate number of tributary channels connected to each time slot interchange unit.

It is not essential that each time slot interchange unit be connected to tributary channels.

For example, the single equipment add/drop multiplexer of Figure 7 need not have any tributary ports connected to one or more of its four time slot interchange units.

Equally, in a distributed add/drop multiplexer as described hereinbefore with reference to Figure 6, the add/drop multiplexer units of some of the nodes need not have any tributary ports.

It will also be understood that, whilst the foregoing embodiments have provided 2-622Mbit/s add/drop multiplexers, the tributary signals and aggregate signals can have different rates than 2 and 622Mbit/s, as required. The North American digital hierarchy rates can be used, for example.

Claims (12)

CLAIMS:

1. Add/drop multiplexer apparatus, for connection to main channels and a tributary channel of a communications network, including a first signal interchange unit, through which a first such main channel passes when the apparatus is in use, having a tributary port for connection to such a tributary channel, which unit is operable to cause an information signal to pass between a first such main channel and that tributary channel when the apparatus is in use, and the apparatus also including a second signal interchange unit, through which the said first main channel and a second such main channel pass when the apparatus is in use, operable to cause the said information signal to pass between the first and second main channels, thereby enabling such an information signal to be transferred between the said tributary channel and the said second main channel.

2. Apparatus as claimed in claim 1, wherein the said second signal interchange unit also has a tributary port for connection to a further such tributary channel and is operable to cause the said information signal to pass between the said first main channel and that further tributary channel when the apparatus is in use.

3. Apparatus as claimed in claim 2, including a third signal interchange unit, through which the said second main channel and a third such main channel pass when the apparatus is in use, which unit is operable to cause an information signal to pass between the second and third main channels when the apparatus is in use, and wherein the said third main channel also passes through the said first signal interchange unit when the apparatus is in use, which unit is also operable to cause such an information signal to pass between its said tributary channel and the said third main channel.

4. Apparatus as claimed in claim 1, 2 or 3, including further signal interchange units, there being as many signal interchange units in total as there are main channels of the network, through which signal interchange units different respective pairs of the main channels pass when the apparatus is in use.

5. Apparatus as claimed in any one of claims 1 to 3, wherein the said communications network is a ring network having four main channels and (8 + 4n) such signal interchange units, where n is zero or a positive integer, arranged at respective connection nodes around the ring network.

6. Apparatus as claimed in any preceding claim, wherein the communications network is a synchronous digital hierarchy network the said main channels of which are provided by respective higher-order virtual containers, and the said information signals are transported through the network in respective lowerorder virtual containers.

7. Apparatus as claimed in claim 6, wherein the said higher-order virtual containers include VC-4 virtual containers, and the said lower-order virtual containers include VC-11 or VC-12 virtual containers.

8. Apparatus as claimed in any preceding claim, including a series of individual add/drop multiplexer devices arranged in series at different respective connection nodes along a transmission line of such a communications network, which transmission line provides the said main channels of the network between the devices of the said series, each device including one of the said signal interchange units and two muldem units, connected respectively to the two sides of the said transmission line at the connection node concerned and also connected within the device to one another and to the signal interchange unit of the device, which muldem units serve to provide access to the individual main channels of the transmission line on each of the said two sides thereof and also serve to connect two of the accessed main channels of one side and the corresponding two accessed main channels of the other side to the signal interchange unit of the device, whilst connecting the remaining accessed main channel(s) of the said one side directly to the corresponding accessed main channel(s) of the said other side.

9. Apparatus as claimed in claim 8, further including, at a hub connection node of the transmission line, a further add/drop multiplexer device including two of the said signal interchange units and also including two muldem units connected respectively to the two sides of the said transmission line at the hub connection node and also connected within the device to the two signal interchange units of the device, which muldem units serve to provide access to the individual main channels of the transmission line on each of the said two sides thereof and also serve to connect two of the accessed main channels of one side and the corresponding two accessed main channels of the other side to one of the said two signal interchange units of the device and to connect the remaining accessed main channel(s) of the said one side and the corresponding accessed main channel(s) of the said other side to the other of the said two signal interchange units of the device, so that at the hub connection node there is access to all of the main channels of the transmission line.

10. Apparatus as claimed in any one of claims 1 to 7, wherein the said signal interchange units are connected together in series within a single add/drop multiplexer device arranged at a connection node along a transmission line of such a communications network, which device also includes two muldem units connected respectively to the two sides of the said transmission line at the said connection node and also connected respectively to the first and last signal interchange units of the said series, which muldem units serve to provide access to the individual main channels of the transmission line on each of the said two sides thereof, and the main channels extending, between each pair of adjacent signal interchange units of the series, along respective channel connection lines of the device.

11. Apparatus as claimed in claim 8, 9 or 10, wherein the said transmission line is a higher-rate synchronous digital hierarchy transmission line STM-N.

12. Add/drop multiplexer apparatus substantially as hereinbefore described with reference to any of Figures 5A to 5D, 6, 7, 8, 9, 10, 11, 12, 13 or 14 of the accompanying drawings.