WO2003105379A1 - System and method for implementing a protocol automatically protecting multiplexing sections across one or several synchronous subnetworks - Google Patents

Abstract

The invention relates to a system and a method for implementing a protocol automatically protecting multiplexing sections (MSP) in a synchronous network (R), in which a synchronous frame is transmitted across one or several SDH-type or SONET-type synchronous subnetworks (RIS, RIN). Said system makes it possible to transfer in a secure manner data across different subnetworks while continuing to allow multiplexing sections to be protected even when transmission errors have occurred in multiplexing sections which are part of independent subnetworks.

Description

 SYSTEM AND METHOD FOR IMPLEMENTING A PROTOCOL FOR AUTOMATIC PROTECTION OF MULTIPLEXING SECTIONS THROUGH ONE OR MORE SUB-SUB

SYNCHRONOUS NETWORKS

The present invention relates to a system and method for implementing an automatic protection protocol for multiplexing sections through one or more synchronous sub-networks, of SDH or SONET type.

The invention relates to the field of high speed synchronous multiplex data transport networks greater than or equal to 155 Mbit / s. It is more particularly situated in the field of automatic traffic switching on a so-called "backup" channel, the implementation of which is carried out from signaling information, in the event of the presence of fault information detected by a termination. MST multiplexing section ("Multiplex Section Termination" in English terminology). It typically finds its application in the implementation of an automatic protection protocol for multiplexing sections MSP ("Multiplex Section Protection" in English terminology), which consists of transporting, completely transparently, ie without modification, the protocol information through one or more independently managed subnets, and to reconstruct fault information detected by one or more terminations of MST multiplexing sections in at least one of the subnets.

The main types of synchronous networks currently known are the synchronous digital hierarchy SDH (Synchronous Digital Hierarchy in English terminology) and the American hierarchy known as SONET (Synchronous Optical NETwork in English terminology). The characteristics of the SDH hierarchy are defined in ITU-T Recommendation G.707 / Y.1322, and those of the SONET hierarchy are defined in the ANSI T1.105 standard. Even if in the following description, only reference is made to the SDH hierarchy, it should not be forgotten that the invention can also be applied to the SONET hierarchy which is based on the same basic principles. The invention will now be described with reference to the prior art: FIG. 1 shows schematically a known STM-N frame, FIG. 2 shows diagrammatically the processes implemented on the reception and re-transmission of an STM- frame N by a section termination module of a subnet. A synchronous frame, called STM-N in the SDH hierarchy, is intended to transport, in the SDH synchronous network, the data to be transmitted, with a fixed period equal to 125 μs. The data to be transmitted are stored in so-called virtual containers, referenced VC throughout the rest of the description, which, when they are multiplexed, form all or part of the useful capacity CA of the STM-N frame. . The header bytes of this STM-N frame form what is called an overhead section SOH ("Section Over Head" in English terminology). They contain specific data relating to the multiplexing section (MSOH) or the regeneration section (RSOH), between two network devices, which the frame must pass through.

The virtual container area VC, in which the data to be transmitted is stored, is called the payload CU. The header bytes of a container contain the management data of this container and define what is called a POH path overhead in Anglo-Saxon terminology.

The position of the virtual containers VC in the STM-N frame is identified by a pointer PTR located in the SOH overhead of the frame which indicates the position of the first byte of the virtual container VC in the payload CA of the frame. The PTR pointer, associated with its virtual container VC (STS-SPE in SONET) constitutes an administrative unit AU ("Administrative Unit" in English terminology). Characteristic data of the protocol information is carried by bytes K1 and K2 located in the overhead of multiplexing section MSOH of the frame STM-N (or in the overhead of line of the frames STS-M or OC-M SONET) with N≥l for a transmission speed greater than or equal to 155 Mbit / s. STM-N frames having a period of 125 μs, the total bit rate transported by these two bytes K1, K2 is therefore equal to 128 Kbit / s.

The functions of bytes K1 and K2 and the associated protocols are described in ITU-T recommendations G.707, G.841 and G.783 as well as in the ANSI Tl.105.01 standard.

The MSP multiplexing section automatic protection techniques are defined in ITU-T recommendations G.841 and G.783 as well as in the ANSI Tl.105.01 standard. They consist, between two adjacent nodes of a network, in replacing a faulty multiplexing section by another multiplexing section reserved for its protection. The protection activation criteria are derived from the processing of certain information present in the MSOH multiplexing section overhead of the transported frames.

Automatic traffic switching, on a backup channel, is carried out in particular on detection, by a section termination of the normal channel, of fault information of type SD ("Signal Degraded"), or of type SF ("Signal Fail"). These SD or SF type defects are well known to those skilled in the art and are defined in the IUT-T Recommendations. SD or SF type fault information constitutes failover criteria. The implementation of this switchover is then carried out on the basis of signaling information carried by bytes K1 and K2 located in the over-speed of the MSOH multiplexing section of the frame transported by the backup channel. It is also important, before and after switching, to be able to detect the above-mentioned fault information on the backup channel.

The main function of SDH networks is to transport and route virtual containers VC (or STS-SPE in SONET hierarchy), containing the data to be transmitted, through a certain number of nodes. The nodes of a network are made up of equipment intended to route traffic. By definition, in the SDH hierarchy (or SONET), any node traversed proceeds to a regeneration and / or multiplexing section termination. Consequently, multiple and successive multiplexing or regeneration section termination operations are performed when transferring a virtual container VC into a network.

In FIG. 2, two modules MST1 and MST4 are shown for terminating the multiplexing section of a synchronous SDH network between which an STM-N frame is routed. An MST2 module of an intermediate subnetwork is shown in dotted lines. The STM-N frame includes, among other things, the virtual container VC to be transmitted and information stored in the overhead of multiplexing section MSOH.

The STM-N frame is not transparent as a whole: in particular, the MSOH multiplexing section overhead is recalculated at each MST section termination crossed. Therefore, with each operation of MST multiplexing section termination, a new STM-N 'frame is created, so that the integrity of the signaling information carried by the bytes K1, K2 on the one hand and the switchover criteria defined by SD and SF fault information is not guaranteed throughout the transmission of an STM-N frame. Thus, the new STM-N 'frame includes new bytes Kl', K2 ', B2' and the same VC virtual container.

Thus, when the frame is transmitted via intermediate subnets, the information according to which transmission faults have been detected on at least one multiplexing section is lost without the automatic section protection mechanism at the ends of the main synchronous network having could be activated. On reception of the frame by the last section termination module MST4, it is no longer possible to know if there have been transmission faults in intermediate multiplexing sections because the information contained in the overhead SOH section values were changed during transmission.

Consequently, when the interconnection of a node with one or more other nodes belonging to the same network requires borrowing one or more other sub-networks, it is important to be able to reconstitute, on the one hand, in the end nodes , the SD or SF type fault information possibly detected in one or more intermediate section terminations of one or more subnets, and on the other hand efficiently and transparently convey the bytes K1, K2, carrying the information of protocol for implementing traffic failover.

Currently owners and users of synchronous networks want to transmit their data traffic anywhere, across one or more independent synchronous subnets, and efficiently, that is to say without the automatic protection of the multiplexing sections being affected.

However, no method known to date makes it possible to ensure the same automatic protection of the multiplexing sections when the traffic passes through one or more intermediate and independent subnets of a main network.

Also, the technical problem to be solved by the object of the present invention is to propose a system for implementing an automatic protection protocol for multiplexing sections in a synchronous network, of which at least two nodes are interconnected by 1 ' intermediate of at least one synchronous subnetwork, and in which a synchronous frame is transmitted between said two nodes, said synchronous frame containing at least one virtual container, containing data to be transmitted, and a multiplexing section overhead, containing section protection protocol information, and which may suffer SD or SF type faults during transmission, which would allow transmission on the one hand, in the transport bandwidth and transparently vis-à-vis the nodes of the subnet, section protection protocol information from a network node to one or more other remote nodes, and on the other hand a reconstruction on, upon reception of the frame by a remote node, information on faults detected by one or more section terminations of the intermediate sub-network (s).

The solution to the technical problem posed is obtained, according to the present invention, because said system comprises: insertion means, capable of inserting into said virtual container said information of the section protection protocol, before the transmission of said frame, restitution means, capable of reconstructing information of said faults, on reception of said synchronous frame, extraction means, capable of extracting said information from the section protection protocol from said virtual container, upon reception of said synchronous frame.

Thus, the protocol information, intended for the implementation of the section protection protocol, is inserted into the virtual container, so that the system according to the invention makes it possible to transmit it without disturbance or modification by the various nodes crossed. This information does not vary throughout the transfer of the synchronous frame. In addition, the system also makes it possible to reconstruct, at the termination of the last multiplexing section, the fault information possibly detected by one or more section termination but not retransmitted in the following sections during the transmission. This restitution of information is based on the presence of transmission errors detected at different levels, either in the last multiplexing section crossed, or in at least one of the multiplexing sections upstream thereof. In the latter case, special processing on the AU administrative units, or on the virtual containers VC transported, is carried out in order to reconstruct the fault information from either the presence of AIS alarm indication signals ("Alarm

Signal indication "in Anglo-Saxon terminology) on all the AU administrative units transported, ie by comparing the B3 error rate of virtual containers

VC at threshold values.

Advantageously, the information of the section protection protocol is inserted in free bytes of the POH overhead rate of the virtual container VC. Thus, the information of the section protection protocol is transmitted transparently, without reducing the bandwidth of the payload of the virtual containers reserved for the data to be transmitted. The solution to the technical problem posed is also obtained, according to the present invention, by means of a method of implementing an automatic protection protocol for multiplexing sections in a synchronous network, of which at least two nodes are interconnected by the intermediary at least one synchronous subnetwork, and in which a synchronous frame is transmitted between said two nodes, said synchronous frame containing at least one virtual container, containing data to be transmitted, and a multiplexing section overhead, containing information from the section protection protocol, and which may suffer SD or SF type faults during transmission.

This method is remarkable in that it consists on the one hand of transforming said synchronous frame in such a way that the information of the section protection protocol is inserted in an area of said virtual container, before the transmission of said frame, and on the other hand, to reconstruct information of said faults, on receipt of said frame. According to another characteristic of the invention, prior to the transmission of the synchronous frame, the following steps are implemented: processing the multiplex section overflow

(MSOH) in order to extract from said synchronous frame, on the one hand the information of the section protection protocol and on the other hand the virtual containers, insert said information of the section protection protocol in a zone of each extracted virtual container of the frame, re-build the frame by re-inserting all the virtual VC containers.

According to yet another characteristic of the invention, the synchronous frame having been transmitted on a normal channel, on its reception, the reconstruction of the information of said faults comprises the steps consisting in: detecting any faults of the SF type which appeared on a last section of multiplexing of the normal channel, and if there is none, detecting possible alarm indication signals in each administrative unit of the normal channel, consisting of a virtual container and its associated pointer, and if there is no there is none, - calculate an error rate, from the value of a B3 byte of parity of the virtual containers of the administrative units of the normal channel devoid of alarm indication signals, and compare it with values thresholds defining switching criteria, and if there are none, detecting any SD type faults which have appeared on said last multiplexing section.

According to yet another characteristic of the invention, the synchronous frame having been transmitted on a backup channel, on its reception, the reconstitution of the information of said faults comprises the steps consisting in: detecting any faults of the SF type which appeared on a last section of the backup channel, and if there is none, detect any alarm indication signals in each administrative unit of the backup channel, constituted by a virtual container VC and its associated pointer, and s 'there are not any, process the virtual containers VC of the administrative units of the standby channel lacking alarm indication signals, to extract the information from the section protection protocol and re-insert them in the frame multiplexing section overflow of the frame , calculate an error rate, from the value of a byte B3 of parity of said virtual containers VC of the standby channel, and compare it with threshold values defining criteria for failover and if there are none not, detect any SD type faults appearing on said last multiplexing section of the backup channel. Other characteristics and advantages of the invention will appear on reading the following description given by way of illustrative and nonlimiting example, with reference to the appended figures which represent: FIG. 3, a block diagram of a system according to the invention, FIG. 4, an example of application of a system according to the invention, FIG. 5, a flow diagram representing the steps of a method according to the invention, prior to the transmission of a synchronous frame , FIGS. 6A and 6B, two flowcharts representing the steps of a method according to the invention, upon reception of a synchronous frame transported respectively by a backup channel and by the normal channel (s) .

FIG. 3 represents a block diagram of a system for implementing a protocol for automatic protection of a multiplexing section of type 1 + 1, through one or more synchronous subnetworks. 1 + 1 protection consists in continuously broadcasting traffic on two different channels: normal N and backup S. The system shown in particular allows the transparent transmission of bytes K1, K2 between the nodes NI and N4 of the same network R, via a RIS subnetwork called "intermediate backup subnet" through which the backup channel S passes and which would correspond to the backup multiplexing section if there were no equipment or intermediate subnet between the nodes NI and N4. The normal N channel passes through the RIN subnetwork called "normal intermediate subnetwork", and which would correspond to the normal multiplexing section if there were no equipment or intermediate subnetwork between the nodes NI and N4 . The NI and N4 nodes are respectively equipped with the section termination modules MSTIS, MST1N and MST4S, MST4N.

The state of the STM-N frame transmitted between the MSTIS equipment and the MST4S equipment is shown diagrammatically before its transmission under the reference 11, during its transmission under the reference 12, and after its reception under the reference 13. This frame comprises on the one hand a useful capacity, containing at least one virtual container VC multiplex which contains the traffic data to be transported, and on the other hand an overflow of multiplexing section MSOH containing the bytes K1, K2, which carry signaling information, also called section protection protocol information in the description.

When a user of the network R for example wants to transport data between the node NI and the node N4, these use the intermediate subnetwork RIN. The intermediate RIS sub-network is used either by this same data, or by non-priority traffic, or by virtual containers VC which are not equipped. In all these cases, virtual containers VC are transmitted in the RIS subnet. To avoid data modification contained in the MSOH multiplexing section overflow, during the transmission, insertion means are provided for example in the MSTIS section termination equipment. These insertion means make it possible to insert into the virtual container VC, the information of the section protection protocol carried by the bytes K1, K2. The protocol information then becomes transparent vis-à-vis the equipment crossed during the transmission of the frame. The new synchronous frame intended to be transmitted to the MST4S equipment is shown diagrammatically under the reference 12. In this new frame the information of the section protection protocol initially carried by the bytes K1 and K2 are protected in the virtual container VC. On the other hand, the byte B2, carrying the fault information and contained in the overflow of the MSOH multiplexing section of the frame, is recalculated (B2 ', B2 ") each time the frame crosses a section termination equipment. .

During the transmission of this frame, the MST2S, MST3S devices of the nodes crossed in the intermediate RIS subnetwork use their own management data, from the bytes contained in the SOH overhead of the frame, without affecting the integrity of the section protection protocol information since it is preserved in the VC container.

If transmission faults are detected in a multiplexing section, upstream of the last DSMN (between MST3N and MST4N) and / or DSMS (between MST3S and MST4S) multiplexing sections, the byte B2 of the frame MSOH overhead recalculated during the transmission of the frame, it is currently impossible to recover the fault information detected in the RIS and / or RIN network, on reception of the frame respectively by the MST4S and / or MST4N equipment. Therefore, in general, when information traffic passes through intermediate subnetworks, the information that transmission faults have been detected on at least one multiplexing section is lost without the automatic protection mechanism of the main synchronous network R being able to be activated.

On reception of the frame by the MST4S and MST4N equipment of the R network, restitution means are therefore provided for reconstructing the fault information which has possibly been detected in the intermediate RIS and RIN subnetworks, as a function of AIS information. on all the administrative units transported or the error rate B3 of the virtual containers VC transported. This restored information is used as a basis for the switching criteria of the automatic protection MSP located in the destination node N4, behind the last multiplexing section terminations MST4N and MST4S.

In addition, extraction means, installed in the MST4S equipment for example, also make it possible to extract from virtual containers VC the protocol information intended to implement the protection in order to re-insert them into the bytes K1, K2. of the MSOH overhead of the frame 13, before transmitting the frame thus restored to the MSP equipment responsible for carrying out the protection.

When the synchronous network is of the SDH type, the virtual container in which the information of the section protection protocol is inserted, is a virtual container of higher order, concatenated or not, of type VC, VC4-xc etc., and the synchronous frame is an STM-N frame with N≥l. This type of virtual container contains, in the POH overhead rate, two bytes F2, F3 left to the freedom of the users. The information carried by bytes K1, K2 can therefore be inserted into these bytes F2, F3 without reducing the bandwidth reserved, in the container payload, for the traffic data to be transmitted. Equivalently, when the synchronous network is of the SONET type, the virtual container in which the bytes are inserted is an STS-SPE, and the synchronous frame is an STS-M or OC-M frame with M = 3 * N and N ≥L. In this case, the free bytes of the virtual container, in which the information is inserted, are F2 and Z3.

In the example shown in FIG. 3, the insertion of bytes K1, K2 is done in the equipment MSTIS transmitting the frame and the reconstitution as well as the extraction are done in the equipment MST4S receiver. However, this is not the only possible case, different embodiments exist.

An example of application of a system according to the invention is illustrated in FIG. 4. In this example, the normal channel No crosses an intermediate subnetwork RI1N between two nodes NI, N4 of a synchronous network R. The backup S channel, meanwhile, crosses several intermediate subnetworks RI1S, RI2S, RI3S between the two nodes NI and N4. These two nodes NI and N4 are equipped with section termination equipment respectively MST1N, MSTIS and MST4N, MST4S and with a multiplexing section protection module MSP1 and MSP4 respectively. Of course, this figure is only an example, all the configurations being possible. Thus, the configuration can be reversed and in this case it is the normal channel No which replaces the backup channel S.

The protection protocol implementation system consists firstly in verifying whether or not there were transmission faults on the last DSMN multiplexing section, then in estimating the transmission errors which have occurred in the (the) intermediate RI1N subnetwork (s) to assess whether they define failover criteria for the main R network. Similarly, the presence of transmission faults on the transmission channel should be checked. backup S. Traffic switching is implemented thanks to the protocol information carried by bytes K1, K2 transmitted on the backup channel S.

A method of implementing an automatic multiplexing section protection protocol is illustrated in FIGS. 5, 6A and 6B. FIG. 5 represents the steps of such a method prior to the transmission of a synchronous frame.

When a multiplexing section termination equipment, MSTIS of FIGS. 3 and 4 for example, provided with insertion means for transforming conventional STM-N frames, receives 100 such a frame coming from another equipment of the same network , it firstly processes 110 the MSOH multiplexing section overhead of the frame. The processing of this MSOH overhead makes it possible to extract 122 therefrom on the one hand the virtual containers of the frame and on the other hand to record 130, in a storage means, the signaling information carried by the bytes K1, K2. The virtual containers of the frame are in fact extracted 122 one after the other until the number n of extracts is equal to the number P of virtual containers present in the frame. For this, a counter n previously initialized 121 makes it possible to count the number of extracted containers 123.

After each extraction from a virtual container, the information carried by bytes K1, K2 is copied from the storage means to dedicated locations of the POH overhead rate of the virtual container (step 140). These dedicated locations are in fact free bytes, that is to say the bytes F2, F3 (F2, Z3 in SONET), reserved for the use of the user.

Copying the information carried by the bytes K1, K2 into each virtual container makes it possible to ensure that the signaling information is found in all circumstances, even when a virtual container has been damaged or lost.

Another step 150 then consists in recalculating a parity byte, byte B3, which is intended to count the number of transmission errors in each virtual container. Indeed, the insertion of the signaling information in the bytes F2, F3 of the virtual container VC creates a modification of the data in the overhead POH. Byte B3, also located in this POH overhead, must therefore be recalculated according to the new data.

This insertion and calculation operation of B3 is carried out on all the containers VC of the frame until their number P is reached (124). The last step 160 before the transmission, by the synchronous network, of the transformed frame, consists in reconstituting this frame, that is to say in re-inserting the P virtual containers VC transformed in the useful capacity of the frame. Several configurations are possible for the protection of multiplexing section. Thus, 1 + 1 protection consists in permanently broadcasting traffic on 2 different channels: normal and emergency. In this case, the traffic is duplicated on the two transmitting channels, and a selector makes it possible to receive it on one or the other of the two channels.

Protection m: n consists in protecting n normal channels with m backup channels. This protection mode is general and is available in 1: 1 protection comprising a free backup channel which can therefore carry, for example, non-priority traffic for a normal channel to be protected, and in 1: n protection comprising a free backup channel for n different normal channels to protect. Faults trigger different types of alarms which in turn activate the implementation of the automatic protection protocol transported by the bytes K1, K2.

Likewise, multiplex section protection can be implemented for different linear or ring network architectures.

FIG. 6A represents the steps of the method making it possible to restore on the one hand the information of defects detected in one or more multiplexing sections of one or more subnetworks and on the other hand the bytes K1, K2 of the initial frame, on reception, by an MSP4 device of the standby channel, of a transformed STM-N frame having been sent from a remote NI node, on the standby channel, through one or more intermediate RIIS, RI2S, RI3S subnets of the emergency channel.

This process initially consists in checking if there were SF type faults on the last DSMS multiplexing section crossed. Thus, a first step 210 consists in verifying whether there has been a fault of the SF type ("Signal Fail" in Anglo-Saxon literature) on the last DSMS multiplexing section. If the transmission has been effectively interrupted, an interruption SF alarm is triggered (step 260) and the MSP protocol for automatic multiplexing section protection is immediately triggered.

When no SF break was detected on the last DSMS multiplexing section, it must be possible to estimate the transmission faults that may have occurred during the transmission of the frame in the subnet (s) (x ) Intermediate RIIS, RI2S, RI3S and assess whether they define failover criteria for the main R network.

For this, it is necessary to extract from the frame, by means of the extraction, each administrative unit AU, that is to say each virtual container VC associated with its pointer. A counter n previously initialized (231) therefore makes it possible to count and increment (232) each administrative unit AU extracted and processed.

The processing 240 of each administrative unit consists in verifying whether the AIS alarm indication signals ("Alarm Indication Signal" in English terminology) have been detected. When AIS information is detected in an administrative unit, the counter (232) increments by one. When all the P administrative units of the frame each have AIS information (233), an assumption is made that there has been a cut in a multiplexing section and a cutoff "SF" alarm is triggered (step 260).

As soon as no AIS information is detected in an administrative unit, the overhead of the POH path is processed so as to be able to extract (step 251) the values saved in the bytes F2, F3 from the virtual container VC and to re-send them. -inject into the bytes K1, K2 of the overflow of the MSOH multiplexing section of the frame. The parity byte B3 of each virtual container processed is then extracted and an error rate is calculated from the value of this byte B3 (step 252). This error rate makes it possible to define the changeover criteria for the implementation of the protection protocol.

The calculated error rate (252) is then compared with SD-B3 and / or SF-B3 thresholds which are for example defined as being identical respectively to the error rate thresholds carried by the byte B2 of the overhead MSOH of the frame activating an alarm respectively SD ("Signal Degradation") and / or SF ("Signal Fail"). Thus, if the error rates B3 are greater than the threshold SD-B3 and / or SF-B3, an assumption is made according to which the error rate is at least identical throughout the frame and that the threshold d corresponding error of byte B2 is also reached. An SD and / or SF alarm is then activated.

Step 253 therefore consists in comparing the average error rate B3 with the threshold SD-B3. If the error rate carried by B3 is less than this threshold, then a step 220 consists in checking whether a defect of the SD ("Signal Degraded") type has been detected on the last DSMS multiplexing section. If the fault has actually been detected, then an SD alarm is triggered (step 255), otherwise, the normal function of the protective equipment MSP is triggered. On the other hand, if the error rate is higher than this threshold, a new comparison is carried out compared to the threshold SF-B3

(step 254). If the error rate is below this threshold SF-B3, an SD alarm is triggered (step 255).

On the other hand, if the error rate is not only greater than the SD-B3 threshold but also greater than the SF threshold, then it is assumed that a transmission interruption has taken place in a multiplexing section and an SF interruption alarm is triggered (step 260).

FIG. 6B represents the steps of the method making it possible to restore the information of defects detected in one or more multiplexing sections of one or more subnets, on reception of a transformed STM-N frame having been transmitted from a remote node NI on the normal channel, through one or more intermediate RIIN subnets.

Besides the fact that it applies to the normal channel and therefore to the information transmitted on this channel, the method differs from the previous one (described with reference to FIG. 6A) by the fact that it does not implement step 251 extraction of the values saved in the bytes F2, F3 of the virtual containers in order to re-inject them into the bytes K1, K2 of the frame overhead. Indeed, according to the standard, the bytes K1, K2 carrying the information of the section protection protocol are only read on the backup S channel but not on the normal channel.

The system and the method which have just been described with reference to the appended figures are only illustrations and are in no way limited to these examples. They typically find their application in the automatic protection of traffic in multiplexing sections. They allow data to be transferred securely across different subnets, while retaining the possibility of performing multiplexing section protection even when transmission errors have occurred in multiplexing sections belonging to subnets. - independent networks. Thanks to the system according to the invention, it is possible to transmit, in a transparent manner, the information of the section protection protocol carried by the bytes K1, K2, between two nodes interconnected by one or more subnets, without reducing the bandwidth the payload of virtual containers reserved for the data to be transmitted. The system also makes it possible to reconstruct information, on reception of the frame, when at least one transmission fault has affected at least one of the multiplexing sections upstream of the last multiplexing section. Thus, it is possible to ensure the smooth running of the automatic protection mechanisms of the multiplexing section between two nodes of a synchronous network interconnected by one or more other subnetworks.

Claims

1. System for implementing an automatic protection protocol for multiplexing sections (MSP) in a synchronous network (R), of which at least two nodes (NI, N4) are interconnected by means of at least one subnet (RIS,

RIN, RIIS, RI2S, RI3S) synchronous, and in which a synchronous frame is transmitted between said two nodes (NI, N4), said synchronous frame containing at least one virtual container (VC), containing data to be transmitted, and one on - multiplexing section rate (MSOH), containing information from the section protection protocol, and which may suffer SD or SF type faults during transmission, characterized in that it comprises: insertion means, suitable inserting into said virtual container (VC) said information of the section protection protocol, before the transmission of said frame, restitution means, capable of reconstructing information of said faults on reception of said synchronous frame, - means of extraction, capable of extracting from said virtual container said information of the section protection protocol, on receipt of said synchronous frame.

2. System according to claim 1, characterized in that said network being of the SDH type, said virtual container is a virtual container of higher order, concatenated or not (VC4, VC4-xc), and said synchronous frame is an STM-N frame with N> 1.

3. System according to claim 1, characterized in that said network being of the SONET type, said virtual container is an STS-SPE and said synchronous frame is an STS-M or OC-M frame, with M =

3 * N and N> 1.

4. System according to one of the preceding claims, characterized in that said information of the section protection protocol is inserted in a zone of all the virtual containers of the same frame.

5. System according to one of the preceding claims, characterized in that said information of the section protection protocol is inserted in the free bytes (F2, F3 when the network is of SDH type; F2, Z3 when the network is of type SONET) of said virtual container (VC).

6. System according to one of the preceding claims, characterized in that the extraction means are installed in equipment (MST4S) for terminating the section of an emergency channel arranged in the destination node (N4).

7. Method for implementing an automatic protection protocol for multiplexing sections

(MSP) in a synchronous network (R), of which at least two nodes (NI, N4) are interconnected via at least one subnetwork (RIS, RIN, RIIS, RI2S, RI3S) and which a synchronous frame is transmitted between said two nodes (NI, N4), said synchronous frame containing at least one virtual container (VC), containing data to be transmitted, and a multiplexing section overhead (MSOH), containing information of the section protection protocol, and which may suffer SD or SF type faults during transmission, characterized in that it consists on the one hand of transforming said synchronous frame so that the information of the protection protocol of section are inserted in an area of said virtual container (VC), before the transmission of said frame, and on the other hand, to reconstruct information of said faults, upon receipt of said frame.

8. Method according to claim 7, characterized in that, before the transmission of the synchronous frame, the following steps are implemented: process (110) the multiplexing section overflow (MSOH) in order to extract from said synchronous frame, on the one hand the information of the section protection protocol (130) and on the other hand the virtual containers (122), insert (140) said information of the section protection protocol in an area of each container virtual extract of the frame, - reconstruct (160) the frame by re-inserting all the virtual containers VC therein.

9. Method according to claim 8, characterized in that, after the insertion of the information of the section protection protocol in each virtual container, an additional step (150) consists in recalculating a byte B3 of parity intended to count the number of transmission errors in said container.

10. Process according to one of claims 8 to 9, characterized in that the information of the section protection protocol is inserted in free bytes (F2, F3 when the network is of SDH type; F2, Z3 when the network is SONET) of each virtual container (VC).

11. Method according to claim 7, characterized in that said synchronous frame having been transmitted on a normal channel (N, No), on its reception, the reconstitution of the information of said faults comprises the steps consisting in: detecting (210; 220) any type SF faults appeared on a last multiplexing section (DSMN) of the normal channel, and if there is none, detect (250) possible alarm indication signals (AIS) in each unit administrative (AU) of the normal channel, consisting of a virtual container VC and its associated pointer, and if there is none, calculate an error rate, from the value of a byte B3 of parity of virtual containers of the normal channel administrative units devoid of alarm indication signals, and compare it (253; 254) with threshold values (SD-B3, SF-B3) defining switching criteria, and if there are no 'there is not any, detect any SD type faults appearing on said last multiplexing section (DSMN) of the normal channel.

12. Method according to claim 7, characterized in that said synchronous frame having been transmitted on a backup channel (S), on its reception, the reconstitution of the information of said faults comprises the steps consisting in: - detecting any type faults SF appeared on a last multiplexing section (DSMS) of the backup channel, and if there is none, detect possible alarm indication signals (AIS) in each administrative unit of the backup channel, consisting by a virtual container VC and its associated pointer, and if there is none, process the virtual containers VC of the administrative units of the emergency channel devoid of alarm indication signals (AIS), to extract the section protection protocol information and reinsert it into the frame multiplexing section overhead, - calculate an error rate, from the value of a parity byte B3 of said virtual containers VC of the channel relief, and compare it (253; 254) at threshold values (SD-B3, SF-B3) defining switching criteria, and if there are none, - detecting any SD type faults appearing on said last multiplexing section (DSMS) of the emergency channel.

13. Method according to one of the preceding claims, characterized in that as soon as SF type faults, relating to a cut, are detected, a cut alarm is triggered (260) and the automatic multiplexing section protection protocol is immediately implemented.

14. Method according to one of the preceding claims, characterized in that when all the (P) administrative units (AU) of the frame include alarm indication signals (AIS)

(233), an alarm (260) SF is triggered and the automatic multiplexing section protection protocol is implemented.