DE602005000072T2 - Network element with multi-level low-order circuit matrix - Google Patents

Description

Territory of invention

The The present invention relates to the field of telecommunications and especially a network element of a transport network with a multi-level Lower order circuit matrix.

transport networks serve as the transport of the physical layer of tributary signals. Such feeders are put together according to the multiplexing rules multiplexed to higher bit rate Multiplexed signals for to form a more efficient transport through the network. A general known type of transmission networks complies with the SDH standard ITU-T G.707, 10/2000. The equivalent US standard of the SDH is called SONET.

In The SDH becomes tributary signals in virtual containers of the corresponding ones Size shown. Virtual containers of lower order become virtual containers higher Order multiplexed. The virtual containers of higher order are mapped into frames where they pass through a higher-order pointer addressed as the pointer of the administrative unit (AU) that will enable them to move freely within the frames to phase and frequency deviations in the network. Accordingly, the virtual containers lower order within the higher-order virtual containers Pointers of lower order addressed as the pointers of the Feeder unit (TU) are designated.

The basic frame structure is called STM-1 (synchronous transport module) designated. Signals higher capacity are obtained by byte-multiplexing the N STM-1 signals, to form an STM-N signal.

virtual Connections referred to as paths are used within the Network through the use of network elements that are capable of these virtual containers from each to each I / O port in the room and time range switch. This process is usually called crossconnecting because such virtual connections are semipermanent Nature are. Such network elements are therefore also called crossconnects designated.

For a SDH network are basically there are two types of crossconnects, broadband crossconnects, the capable are higher, only virtual containers To switch order, and long-range crossconnects that are capable of both virtual containers higher To switch order, as well as lower order.

The core of a crossconnect is its circuit matrix. Depending on the required matrix capacity, some crossconnects use a square circuit matrix while others have a multi-level circuit matrix, such as a clos matrix. Wideband crossconnects often have a higher order circuit matrix and a separate lower order circuit matrix. A generalized logical block diagram of such an architecture is described, for example, in ITU-T G.782 01/94, 3 - 9 , shown.

In The existing networks creates a need for more and more coupling capacity with the Increase in traffic, especially in urban area networks. On the other hand wish Network operators more compact and less expensive network elements that require less space while at the same time less power consumption and reduced heat dissipation to be provided. Consequently, it is an object of the present invention Invention to provide a high capacity compact wide band crossconnect.

Summary the invention

These and other objects, appearing below, are achieved by a network element for a transport network of the type discussed above having a lower order three-stage circuit matrix including:
an input matrix stage and an output matrix stage, both of which include a plurality of hybrid arrays for switching the lower order multiplex units or the higher order multiplex units; and
an intermediate stage comprising a plurality of matrices capable of switching only higher-order multiplex units, wherein each of the plurality of mid-stage matrices is connected to each of the first input-stage matrices and each of the output-matrix stage matrices.

Of the Matrix design according to the invention is very beneficial because the same mid-stage matrix components for the Circuit matrix lower order can be reused, the for one Circuit matrix higher Order must be developed anyway. This reduces the development time and the costs drastically. Preferably, the input and output stages become arranged on the crossconnect I / O PCBs. That leads to a very compact design and has the added advantage of having a broadband crossconnect into a wide-band crossconnect by simply replacing the I / O PCBs changed can be.

Summary the drawings

A preferred embodiment The invention will now be described with reference to the accompanying drawings in which show

1 a generalized logical block diagram of a wide band crossconnect;

2 the architecture of a lower order crossconnect matrix according to the invention;

3 the hardware architecture of a lower order matrix I / O circuit board for use in a wide band crossconnect according to the invention;

4 the physical structure of a wide band crossconnect using the invention;

5 schematically the operation in the lower order matrix;

6 a network element having a three-level lower-order circuit matrix; and

7a and 7b the rearrangement of broadband and long-range connections in a final stage module.

detailed Description of the invention

The basic implementation of a wide-band crossconnect, as known, for example, from ITU-T G.782 (01/94), is shown as a block diagram in FIG 1 shown. It contains an input / output port 11 with a line termination function 12 that with a crossconnect matrix 13 higher order is connected. The crossconnect matrix 13 is via an assembler function 14 higher order with a crossconnect matrix 15 higher order connected. For simplicity, only one I / O port and only one matrix connection is shown, although it should be apparent to those skilled in the art that each matrix has a number of matrix connections and that a number of I / O ports are available in a crossconnect ,

The function of this architecture is as follows. An STM-N signal is sent to the I / O port 11 where the section overhead is received by the line termination function 12 is ended. This function is also referred to as the transport completion function (TTF). Higher-order multiplexing units of the AU-4 or AU-3 type are passed through the matrix 13 higher order of each cross-connected to each I / O port. This feature is known as the higher order way link (HPC). If lower-order access is required, ie, if the lower-level virtual container level VC-3 (for SDH only) VC-2, VC-12, or VC-11 is to be cross-referenced between any two I / O ports, then these signals are applied to the corresponding matrix connections via the assembler functions 14 higher order on the matrix 15 switched lower order, where lower-level pathways (LPC) are built. The higher order assembler includes a higher order path termination function (HPT) and a higher order path adjustment function (HPA). An example of an HPA function is in EP 0 440 128 B described.

The invention provides a scalable implementation of the functional blocks 14 and 15 which allow a very high volume of traffic at low cost and high density. This is accomplished through the use of a three-stage matrix where only the input and output stages perform lower order switching while the mid-stage of the matrix switches only the higher order multiplex units, ie VC-4 or VC-3 or both.

The use of a middle stage switching only high-order connections significantly reduces their complexity and cost. However, this causes some loss of capacity because some Ver higher order bonds to and from the middle stage can not be filled with lower order connections. It can be explained that the number of wasted higher order connections to (or from) a final stage need not exceed the number of final stages. The invention thus proposes a design where the number of output stages is small compared to the number of higher order connections from a final stage and where the loss due to incomplete packaged internal connections is consequently negligible.

The principle of the invention is in 2 shown. The crossconnect matrix has as its middle stage CS a quadratic matrix which is capable of switching only at the level of the higher order multiplex units, preferably at the VC-3 level. The middle stage in the preferred embodiment has a total capacity of 640 Gbit / s, ie of 4096 STM-1 equivalents. The input stage IS and the output stage OS each consist in this embodiment of 8 lower order switching modules. Each lower-level switch module of the input stage has two inputs and four outputs for STM-64 signals. Conversely, each module of the output stage has four inputs connected to the middle stage and two outputs for STM-64 signals. Each module of the input and output stages thus has a capacity of 20 Gbit / s, or in other words 128 STM-1 equivalents. The reason for this is that a 1: 2 expansion in the final stages is required to support the function of subnet connection protection (SNCP) in a non-blocking manner. However, if SNCP support is not required, or if blocking can be tolerated under certain conditions, then each power stage module can have as many inputs as outputs.

While the internal connections between the input stage, the middle stage and the output stage in 2 As shown as 10 Gbit / s connections (ie, inner STM64), it is preferred to multiplex the inner signals down to 2.5 Gbit / s (ie, the inner STM16), which can be readily implemented as a backplane bus.

The input stage modules and the output stage modules are physically located on the same I / O PCBs. An exemplary I / O circuit board 300 is in 3 shown. It contains connections for two optical fibers 301 and 302 each transmitting an STM64 signal. The optical fiber 301 comes with an opto-electrical converter 311 connected, which converts the received optical signal into an electrical signal, which on an additional processing unit 321 to be led. The auxiliary processing unit demultiplexes the 10 Gbps STM64 signal into four STM16 signals, extracts and processes the section overhead, and forwards a 2 MHz reference clock signal 381 from. The additional processing unit 321 is using a TU pointer processor 331 which performs higher order way termination and matching on the individual VC-4 or VC-3 signals included with the STM16. The optical fiber 302 is then again with the opto-electrical converter 312 connected via the auxiliary processing unit 322 on the TU pointer processor 332 to be led. The TU pointer processors 331 and 332 be with the inputs of a switching module 341 connected to a lower order, which forms part of the input stage of the 3-stage matrix arrangement, which in 2 is shown. The outputs of the matrix module 341 be with a backplane interface 350 connecting the backplane of the crossconnect and providing a function of the device protection circuitry (EPS) between the middle stage copies A and B.

As in 3 is shown is a direct connection between the 1st stage 341 and the 3rd stage 342 present on the same card. It could be used to guide the lower order links that remain on the same card and that would reduce the load on the middle level and the potential blocking probability. This feature is not necessarily used in an implementation of the invention for the ETSI SDH, but it could be used to advantage in an ANSI implementation (ie, SONET implementation).

Also, the I / O board indicates 300 a board processor 360 which can be readily implemented as an FPGA (Field Programmable Gate Array). The processor 360 receives the extracted overhead bytes from the additional processors 321 and 322 , preprocessing the performance monitoring (PM) data and alarm filtering, and sending the PM raw data to the backplane interface 350 for in-band signaling. Additionally, the processor configures 360 the TU pointer processors 331 and 332 to the current multiplex structures within the corresponding received STM64 signals. Finally, the I / O board contains certain support functions, such as a circuit 371 for administrative access, ie for downloading the FPGA and controlling the opto-electrical converters 311 and 312 , an integrated power supply 372 and a voltage controlled oscillator 373 to generate the system clocks. A control line 382 establishes the connection to a common module frame controller.

In the transmit direction, the inner signals from the middle stage matrix CS become from the backplane at the backplane interface 350 which extracts the in-band channel information and the inner STM16 signals to the inputs of a switch module 342 lower order, which is part of the output stage of the Clos matrix of 2 forms. The outputs of the switching module 342 be via the TU pointer processors 331 and 332 according to the additional processors 321 and 322 where the signals are multiplexed to form the output STM64 signals and the section overhead bytes as from the processor 360 received, be inserted. The STM64 signals are then converted into the optical signals by the transducers 311 and 312 converted and corresponding to the optical fibers 301 and 302 Posted.

4 shows a front view of a mounted wide band crossconnect system, which consists of a broadband crossconnect 41 and an expansion subframe 42 lower order exists. The system uses the system of a conventional broadband crossconnect 41 such as the Alcatel 1678 Metro Core Connect. In the figure contains the broadband crossconnect 41 a module frame with a back panel, fans on the top and bottom, and 20 slots for circuit boards. Slots 1 and 20 are not visible from the front panel as they carry bus termination boards for the high speed backplane bus. Slots 2 through 9 and 12 through 19 carry the I / O boards, and slots 10 and 11 support the matrix boards, which work as matrix copies A and B respectively. Each array board contains a higher order square matrix that provides a total capacity of 4096 STM-1 equivalents. Each I / O board terminates 4 external fiber-optic cables that transmit STM64 signals.

each I / O board has four I / O ports for STM64 signals. The back wall connects the I / O boards and matrix boards at 2.5 Gbits / s together. The STM64 signals, which were received at the I / O ports of the I / O boards thus demultiplexed into corresponding four internal STM16 signals. Each matrix board is capable To switch AU-3 contained in the inner STM16 signals. This allows the complete support for SONET signals. For ETSI signals switches the matrix AU-4 like three adjacent concatenated AU-3 in parallel, whereby also the complete Support for ETSI signals allows becomes.

Most of the hardware of the broadband crossconnect 41 also applies to the expansion module frame 42 used lower order, where only the I / O cards through the I / O cards of 3 be replaced. The only change that must be made to the matrix boards in slots 10 and 11 concerns the firmware (FPGA code) on the boards to allow processing and storage of lower order PM data rather than the higher order PM data enable. However, the processing of the PM data is well known to those skilled in the art.

As described above, each wideband crossconnect I / O board has four STM64 ports, while each expansion cage frame I / O board has only two STM64 ports. The I / O boards in slots 15 through 18 of the broadband system 41 are used for internal connections between the wideband system and the expansion subframe. The I / O board in slot 19 is used as a replacement board to replace a defective board in the event of a failure. In the expansion subframe 42 For example, the I / O boards in slots 2 through 9 are used for low-level path access while the boards in slots 18 and 19 are used for device protection purposes. Slots 12 through 17 of the expansion system 41 could stay empty or could work in the same way with slots 12 through 14 of the broadband system 41 be used. The I / O ports of each I / O board from the system 41 , which is used for internal connections, uses four fiber optic cables with the two I / O ports of the two I / O circuit boards of the expansion subframe 42 connected. For example, the printed circuit board is in slot 15 of the module frame 41 with the circuit boards 2 and 3 in the assembly frame 41 connected. In the same way, the replacement printed circuit board in the slot 19 of the module frame 41 with the two spare PCB's in slots 18 and 19 of the module frame 42 connected. From the expansion subframe 42 lower order, the internal signals to the system 41 higher order, where they are switched to the corresponding output ports.

The operation of the matrix arrangement according to the invention is schematically shown in FIG 5 shown. Three input stage modules 510 . 520 . 530 , three output stage modules 550 . 560 . 570 and the middle stage matrix board 540 are shown. The example shows three VC3s per input and per output stage module, eg 511 . 512 and 513 for the module 510 , It should be understood, however, that in reality each module has a capacity of 128 (ie 2 x 64) STM-1 equivalents and therefore processes 384 VC3.

The lower order switching, shown as thin lines through the final stages IS and OS, occurs only in the input and output stage modules. Conversely, the middle stage CS switches only higher-order virtual containers, ie VC-3 in the preferred embodiment. This is represented by the gray shaded "lines" crossing the middle stage CS. A VC-12 operating in the VC-3 522 at the input stage module 520 is included and that for the output VC-3 573 at the output stage 570 is determined by the module 520 in space and time to a VC-3 mid-stage matrix connection to the module 570 connected. In other words, the VC-3 connections are established via the middle stage matrix to interconnect the various input stage modules with the different output stage modules as required. In the input stage, a lower order VC destined for a particular output stage module is packed into an internally used VC-3 which passes through the middle stage to the corresponding output stage module and at the output stage module the lower order VC is removed from the inner VC-3 extracted and assigned to the corresponding output destination, ie the VC-3 573 in this example.

It is preferably in this context, that the VC lower order be packaged in an optimized manner into the VC-3 mid-level compounds. If a connection for a feeder of lower order must be set up on one already existing but partially filled VC-3 connection the first and the third Step matrix module to be reused. Only if that is not possible because all VC-3 leading to the affected output stage module are completely filled, a new VC-3 connection is established by the middle level.

It is also possible to set up the connections for the entire VC-3 and not for smaller tributaries. That's for VC-3 511 shown. In addition, subnet connection protection (SNCP) is performed in the output stage modules. That's for the VC-3 551 . 552 . 561 and 571 shown. The SNCP means that a trib is transmitted over two independent paths, ie the active path and the spare path, and that the better of the two signal copies is selected at the terminus of the SNCP. To fully support the SNCP, an expansion of the matrix capacity from 128 STM-1 equivalents at the input stages to 256 STM-1 equivalents to the middle stage is envisaged.

In the specific embodiment Both the input and output matrix stages are capable, the VC-3 and the VC-12 which are the most commonly used multiplexing units in ETSI SDH systems. Alternatively, one developed for the US SONET market System capable, the VC-11 instead of the VC-12 in addition to switch to the VC-3. It would be also possible, to operate the VC-11, VC-12 and VC-2 within a single system, but with the restriction, that these grouped into VT groups where each VT group is either one can contain single VC-2 or three VC-12, or four VC-11, but that within any such VT group does not mix different VC types (VC-11, VC-12) is allowed.

The partially used VC-3 compounds can not be completely avoided become. To cope with it in all situations, the capacity of the final stage modules preferably from 128 to 125 STM-1 equivalents for the reduced sixteen power amplifier modules. The extension in the entrance level is then 125: 256.

by virtue of the deletion It is possible for connections of lower order feeders to occur after one certain time a big one Number of partially used internal VC-3 compounds can remain. This situation can be done by performing an optimization of the internal connections are improved, i. by repackaging connections in the input and output stages. To the time for To reduce the connection structure, the optimization should be carried out be if the ratio between the used and the necessary higher order connections increases, for example after a configurable number of cross circuits the lower order virtual tributary has been released.

The The principle of the wrapping algorithm is as follows: For each Pair of the first and third levels will be compounds lower Order of some higher order compounds, preferably those who are least populated, to other higher order compounds moved, preferably those that are most occupied until at the most a connection higher Order remains partially occupied. The old and the new connections lower order can at the same time for exist a certain time (bridge and which can provide uninterrupted repackaging, even if the three stages are not synchronized.

6 shows in a second embodiment a network element with a three-stage circuit matrix of lower order, preferably a Clos matrix. The matrix has an input matrix stage IS and an output matrix stage OS. Both include a plurality of hybrid arrays dedicated to switching the lower order multiplex units or the higher order multiplex units as described above with respect to the first embodiment. The middle level, on the other hand, contains a plurality of matrices capable of switching only the higher order multiplexing units. Each of the plurality of middle stage matrices is connected to each of the first input stage matrices and each of the output matrix stage matrices.

In In this respect of the invention, it is possible to choose the intermediate level several smaller modules instead of a single large broadband switch. It is beneficial to have several small broadband mid-stage modules in a Clos configuration instead of a single big one To use middle level matrix. This improves scalability, reduces the cost of the manufacturer and increased the flexibility for the Customers.

There the broadband middle stage is realized as multiple modules requires this is the rearranging of the paths through the intermediate CS. The classic Rearrangement algorithms can adapted to the new configuration.

It may be necessary to optimize the system every now and then inefficiently used broadband paths by "repacking" the VC links (virtual containers, also known as VT connections (virtual tributary connections) in the SONET terminology) within broadband paths, in such a broadband time slot on a backdrop between the intermediate CS and the input stage IS or the output stage OS is cleared.

The modules of the input stage IS and the output stage OS are hybrid broadband / wide band switches. Their inputs and outputs are still broadband lines carrying wide band or broadband connections. Compared to 2 Now they are several middle stage matrix modules and each of the modules of the input stage IS and the output stage OS is connected to each of the middle stage modules in a symmetrical pattern.

In dependence on the number of intermediate levels and the capacity of the different ones Broadband links can be blocking, changeable, or blocking the system exclusively be free from blocking. The preferred configuration is usually changeable unblockable.

The broadband paths are established between the modules of the input stage IS and the modules of the output stage OS in dependence on the broadband and wideband traffic patterns. When a new broadband path is required (either because of a new broadband or new broadband connection), it may first be necessary to "repack" the existing wideband connections to clear a broadband link. It is advantageous to enable broadband links so that an intermediate stage will have free links to the input stage IS and to the output stage OS used by the new connection. If this is not possible, the mid-range broadband paths must be rearranged. This is not completely classical because the input stage IS and the output stage OS are wide band switches, ie capable of switching higher and lower order virtual containers. It turns out that the classical rearrangement algorithms can be adapted to determine the paths through the middle stage. When rearranging a broadband path carrying long-range links, it is necessary to redirect all such links from the old broadband link to the new broadband link in the affected IS and OS modules, see 8th , This can be done in a synchronous "uninterruptible" manner or using a "bridge and roll" algorithm.

7a shows a traditional broadband rearrangement. One (or more) broadband connection (s) in a final stage IS or OS are connected by the old one (P2a, long bar) to a new (P1a, short bar) middle stage module.

7b shows a rearrangement in the proposed system. An amplifier switches broadband (double lines) or wide band (single lines). In a broadband rearrangement, all wideband connections that use the old (P2b, long bar) broadband connection to an intermediate level are connected to the new (P1b, short bar) mid-level module.

It should be noted that the construction details and characteristics described above with respect to the first embodiment are also applied to the second embodiment accordingly can. It should also be noted that the power stages described above can support both broadband and wideband connections.

By doing a preferred embodiment the invention has been described in detail, should be apparent to those skilled in the art be clear that different Modifications and changes carried out can be without deviating from the conceptions of the invention.

Claims (10)

Network element for a transport network designed for the transport of framed multiplexed signals whose signals comprising higher order multiplexing units are capable of transmitting lower order multiplexing units; wherein the network element comprises a three-level lower-order circuit matrix ( 15 ), characterized by an input matrix stage (IS) and an output matrix stage (OS), both including a plurality of hybrid arrays configured to switch the lower order multiplex units or the higher order multiplex units; and a middle stage (CS) comprising a plurality of matrices capable of switching only higher-order multiplex units, wherein each of the plurality of matrices of the middle stage (CS) is associated with each of the first matrices of the input matrix stage (IS) and each the matrix of the output matrix stage (OS) is connected. Network element according to claim 1, in which the lower-order multiplex units within the higher-order multiplex units are addressed by pointers of the feeder unit, and in which the network element is feeder unit pointer processors ( 14 . 331 ) for adjusting the pointers of the feeder unit. A network element as claimed in claim 1, in which the multiplexed signals comply with ITU-T Recommendations for SDH in which the higher order multiplexing units comprise VC-4 or VC-3 virtual containers and the lower order multiplexing entities comprise VC-3, VC virtual containers -2, VC-12 or VC-11, and in which the middle stage (CS) is capable of switching at least virtual containers of the VC-3 type and the input matrix stage (IS) and the output matrix stage (OS) are capable of at least two to switch types of virtual containers of lower order. Network element according to claim 1, in which the three-stage Lower order circuit matrix is a Clos matrix. A network element according to claim 1, further comprising a circuit matrix ( 13 ) of higher order connected in series with the circuit matrix ( 15 ) of lower order. Network element according to claim 1, in which the input stage and the output stage comprise a number of switching modules ( 341 . 342 ; 510 . 520 . 530 . 550 . 560 . 570 ), and in which an input stage module ( 341 ) and an associated output stage module ( 342 ) physically on an I / O circuit board ( 300 ) of the network element are arranged. A network element according to claim 6, wherein the plurality of mid-stage arrays physically arrange one or more matrix boards ( 540 ) and in which the I / O circuit board ( 300 ) and the one or more matrix boards ( 540 ) are connected by a backplane of the network element. Network element according to Claim 6, in which the input stage module ( 341 ) and the associated output stage module ( 342 ) physically on the same I / O board ( 300 ) have a direct connection for lower order connections remaining on the same I / O board. Network element according to claim 1, in which the input stage (IS) an extension of at least 1: 2 from their entrances to their outputs having. Network element according to claim 1, which is adapted to optimize the establishment of higher order inner connections at the intermediate level (CS), by rearranging the device of links lower Order in the input stage (IS) and in the output stage (OS) perform, by the number of partially filled inner multiplex units higher To minimize order.