DE4391854C2 - Method for configuring a time-space-time cross-connection and a device for cross-connection using this method - Google Patents

Description

The invention includes a method for non-interrupting configuration a cross connector for digital data transmission connections, in which Operation change the requirements for the cross connection. The invention relates also a cross connection device using this method and the Use of this device for cross connection.

The Synchronous Digital Hierarchy (SDH) contains a very large and developed one Object unit for the transmission of time-division multiplex signals in a telecommunications onsnetzwerk, the backbone network, which were encrypted by separate PCM Connections to a cross-connection network controlled independently of the computer developed. The standard recommendation CCITT G.707 defines the signals of a first one Level of a synchronous transport module (STM-1) for SDH signals that have an over transmission speed of 155,520 Mbit / s. The basic STM-1 frame is composed of bytes (8 bits), of which 2.430 each the control block ent hold; then an STM-1 frame transmits 63 subsystem containers (e.g. TU-1 Subunit that transmits a 2 Mbit / s signal from usually 30 channels of a PCM  Systems may contain). The STM-1 frames are like 8,000 times every second repeated, which is also the case in the subsystem; each byte of the Frame a 64 kbit / s channel. The SDH signals or transport modules are shaped in that the bytes overlap on the subsystem signals.

An SDH cross connector (DXC) can transfer data between different SDH Levels transfer and traffic between different signals switch. A typical higher level cross connection (DXC, digital cross ver binding, CCITT draft for the standard recommendation G.sdxc-1. . . -3) is the so-called 4/1 Cross-connection, with channels with 2 Mbit / s between the input and output interfaces are switched. An important task of the cross connection is the To optimize the degree of utilization for the capacity of the network transmissions. Farther it must be able to enable flexible reconfiguration or To re-establish connections of the network and the quick initialization of Ensure reserve connections in the event of a fault in the network. The The CCITT SDH standard recommendations listed attempt a logical function define, e.g. B. a functional structure of devices, but they avoid a detail Structured description of these devices.

The digital cross-connection has been studied in great detail to find an architecture that meets the optimal conditions. A structure that very largely fulfills the requirements with regard to capacity, non-interrupting properties and implementation is the TST structure (time-space-time = time-space-time) or the time-space-time cross connection as it is is shown schematically in FIG. 1. In the TST connection structure, the task of finding a non-interrupting connection requires a lot of computing power, although the TST switch is in principle non-interrupting. The need for an intensive calculation is partly due to the large number of bytes or channels, such as those contained in the STM-N signals. An improvement of the TST architecture is that the size of the cross connector is designed for the required connection capacity, so that the technical implementation is more economical than with other architectures (e.g. STS etc.).

In conventional architectures for the TST cross-connection is the cross-connection partially or completely executed twice, which improves possibilities for Allow calculation of a non-interrupting connection. This is at for example in central offices where 2 Mbit / s connections with the Are connected and where the main task is Fast connection establishment and termination of individual channels  Establish connections that work at 64 kbit / s. In case of using one TST switch in a central office must have a free connection through the switch Switch found within limits due to time constraints are blocked, which can also be tolerated if the order switch would have free capacity because the blocking affects only one channel at a time. Such a mode of operation is unacceptable in cross-connections that If possible, data transmission lines affect all inputs at the same time ben to combine to corresponding expenditure. The connection times on the ver Lines of connection are long and the connections do not become particularly fast changed. A basic condition when setting up the connecting lines is it further that the capacity of the connecting lines and also the Querver loyalty can be used efficiently, in contrast to central offices, which also have an oversized capacity to prevent Interruption situations can be achieved.

In conventional SDH cross connections using the TST structure, the problem of finding a non-interrupting connection has been avoided by increasing the capacity of the room switch, for example by doubling the frequency of the room switch. Input signals I1 are located on the left side of FIG. 1. . . to In (here STM-1 signals) and on the right side there are output signals O1. . . to On. The time switch Ti1. . . to Tin and To1. . . to tone on the input and output sides change the positions of the bytes (within a frame) within a signal. The central Raumum switch S connects a signal from a time switch with a signal that is connected to another time switch. A time segment or a byte forms a 64 kbit / s channel. In principle, the time switch is made up of storage elements and the room switch is made up of switching elements. The cross connection is usually set up in a modular structure. The first time switch and the room switch affect a non-interrupting connection from each time segment of an incoming connection to the correct outgoing connection. The time switch on the output side does not affect the execution of a non-interrupting connection, it only switches the channels or the time segments in the correct order that is required by the outgoing connection.

A generic prior art is known from DE 42 28 694 A1, which a switching matrix for switching multiplex signals with a first time header pelfeld, a space switching matrix and a second time switching matrix. Likewise  are data streams (1... N) with high speed and serial arrangement with a logical frame structure in bit and byte structure. With a Such switching matrix are uniform D 156 signals in a pulse frame from 152 rows and 64 columns with one byte each.

The object of the present invention is to provide a method for the cross-connection of Show SDH signals and an architecture in which this method implements is tiert that can realize a non-interrupting connection and known Avoids shortcomings and disadvantages.

The object of the invention is achieved according to the features of Claim 1 by a method for calculating the configuration, which in peri odd intervals. The structure of the cross connection is above that also developed using the method according to claim 6 for the design of Connections to secure the guidance information. Other preferred execution forms of the invention are set out in the dependent claims.

The invention has the advantage that the total capacity of the cross connection is being used. No additional capacity to cross-connect is needed to make one ensure uninterrupted functioning. It is also possible to use the method according to the invention to implement a synchronized mode of operation or to enable error-free switching of the cross-connection modules, who work with the same clock.

The invention is applicable in a synchronous digital hierarchy (SDH) for ver binding of standardized transport modules (STM-N). The invention is also applicable to a compound corresponding to the plesiochronic trans mission hierarchy (PDH). The method according to the invention can be used for cross-connection on devices of different levels, e.g. B. in a 4/1 cross ver binding or in a 3/1 cross connection, the signals of 2 Mbit / s on one level of 34 Mbit / s transmitted.

The invention is illustrated below by means of examples with reference to the following figures explained.

It shows:

Fig. 1 illustrates the basic principle of the time-space-time cross connect,

Fig. 2 shows schematically the control of the cross-connect according to the invention,

Fig. 3 is a simplified flow diagram of the periodical method according to the invention,

Fig. 4 in a simplified flow chart of the inventive method for selecting a time segment to be joined,

5 shows an embodiment of a. 1: N / N: 1 routing backup of.

Fig. 1 shows the principle of a time-space-time cross connect, which is used also in the invention and has already been described in the introductory description. FIG. 2 shows a structure 10 of a TST cross-connection, on the basis of which the method according to the invention can be implemented and in which the control unit 20 of the cross-connection for the simultaneous control of all time switches 1. . . N the input side is suitable for establishing the mutual connections of L time segments. The room switch is made up of N _* N switches, which enable the connection of N inputs to N outputs. On the output side there are again N time switches, which enable the mutual connection of L time segments.

The controller 20 of the cross-connection in FIG. 2 is able to simultaneously (and synchronizes) the switching of the incidence matrix (CM) (or the connection plan) 31 , so that the time and space switches during the change of the connection configuration completely according to the new connection configuration can be configured again. In this way, the processor 30 has an active incidence matrix 31 and, as a backup for execution, a standby incidence matrix 31 b (not shown here). The configuration calculation unit 32 of the processor 30 , which controls the cross-connection, uses the configuration method described below to generate a new configuration which is stored in the standby incidence matrix, on the basis of which the connection configuration is updated. The configuration calculation unit has as input data the distribution of the channels on the input side and the desired outgoing connection for each channel. The control unit 20 for the cross connection uses the renewed matrix 31 b when it controls the time and the room switch suitable for the new connection configuration.

The actual implementation of the calculation for configuring the cross connections according to the invention is based on the property of the TST cross connection that the new configuration can be solved simultaneously for one time segment at a time. In other words, if it is possible to find an uninterrupted state for an arbitrary time segment K via the N time switch on the input side and the N _* N room switch, one can be sure that the other time segments K + 1, K + 2,. . . , L can be determined using this principle. Accordingly, the configuration of the cross connection can be calculated successively for each of the time segments, so that the non-interrupting connection configuration by means of the time switch on the input side and the room switch for the rest of the time segments K, K + 1, K + 2. . . , L can be found.

The room changeover of a certain time segment is not interrupting, if all outputs of the room switch are used. In other words, the Time switch on the input side must include all time segments or channels connect others that all multiplex time segments on the input side of the room are connected to different editions. There is no time segment on the input side that is linked to a specific output it is of course not necessary to use this edition. So that's it the function of the time switch on the input side before the room switch Distribute channels evenly across the time segments so that the room switcher can switch to the correct, desired expenditure. In particular, in the room switch such an interruption situation can be avoided in which a single time segment using more than one channel on the same output time segment should be connected.

With the method according to the invention, the configuration calculation unit determines the incidence matrix in such a way that the cross-connection according to FIG. 2 functions without an interruption.

In response to a request for a connection, the calculation unit 32 sets up a new incidence matrix 31 b (not shown) in a background calculation, which is stored in the memory of the processor 30 . When the calculation of the incidence matrix 31 b has ended, the control unit 20 completely renews the states of the cross-connection modules in accordance with the new incidence matrix. In this way, new connections are added to the incidence matrix or old connections are deleted from it, whereby all cross-connections are reconnected according to the new connection situation. In this way, old connections that are also maintained after changing the connection configuration can also receive a new connection through the cross-connection. More specifically, the connections are renewed with the aid of a synchronized signal, which is provided by a predetermined clock pulse, immediately before the new configuration becomes valid. This synchronizing signal ensures that the old connections, which have to be maintained from the incoming line to the outgoing line, are not disturbed when the incidence matrix is renewed.

In the method for establishing connections, the cross-connection configuration is calculated individually for each time segment. First, the input channels or the bytes of the frame are divided into as many groups as signals or time segments are to be cross-linked using the transport module. For example, an SDH STM-1 connection, which is connected to the time switch on the input side, has a transmission speed of 155 Mbit / s, 63 periods or subsystem stem containers of signals with 2 Mbit / s (for example TU-1, sub-unit, the can contain a 2 Mbit / s signal of usually 30 channels of a PCM system). The position within a frame of each period, which is selected according to the invention, is generated directly by means of a standard pointer or is calculated with the aid of this pointer. Correspondingly, a connection of a plesiochronic transmission hierarchy (PDH) at a speed of 140 Mbit / s contains 64 periods of 2 Mbit / s each. Within each of the groups defined in this way, the cross-connections are established in that the connection configuration implemented in this way is selected such that the still uncalculated time segments can also be connected. As a result, the solution for the complete cross-connection switchover can be implemented by the periodic method according to FIG. 3.

With this method, in which a tested connection time segment is calculated, those time switches which are connected to completely occupied inputs and outputs of the room switch or which have as many unconnected channels as the remaining time segments are selected first. The decisions about the connections are first made for this group, which is called the so-called priority group. Those expenses that are not fully occupied do not necessarily have to be used for every time segment. This means that those inputs and outputs that are in constant use must also be used in this time segment. However, other free connections can remain disconnected if no matching channels are found. According to FIG. 3 starts Auswahlope ration with the program point "Start". The first step is to establish a non-interrupting connection via the time switch and the room switch for the time segment to be executed. Then it is checked whether all time segments are calculated or connected. If there are time segments that still have to be connected, the process starts again with "Start" and the non-interrupting connection is calculated for the next time segment. After the last time segment has been calculated, the process ends with "End".

Fig. 4 shows as a flow chart the selection process for a single time segment. After the start, the test block S1 is next processed, in which it is checked which inputs and outputs can be selected when a connection between the inputs and the outputs is sought. The said priority group is always selected first. If no priority connection is found, the other inputs and outputs for the selection process are examined.

In the second step S2 of FIG. 4, the solution for a time segment is found in the calculation unit 30 in such a way that the output of each unconnected byte is processed first, for which there are at least options for the remaining time segments, for example the smallest Number of channels from different inputs is available. The selection is of course made for those editions of the room switch that were not previously selected during the solution for this time segment, for example those that are still free. The outputs that are still free to choose from are already checked in start step S1, as can be seen in FIG. 4. In other words, it first checks which output can be selected and then finds the output that has the least number of channels coming in from different inputs. If the output has been selected, the selection of the input can in principle be continued.

If the input is selected in step S9 according to FIG. 4, the number of connections to be established, an input-side time switch with a single output-side time switch, is used. In other words, the input-side time switch that has the largest number of channels for the already selected (S2) output is used. Exactly for these cases, the inputs that have already been processed are not considered any further and this is checked with test step S1 of FIG. 4 immediately at the start of the selection of a connection pair and also in step S1 when selecting the output.

Check block S1 thus first ensures that the output is selected can and that the input can then be selected. The selections are made performed only after the exam. The criterion for choosing the output is based  on the improvement in finding a non-disruptive connection for the last connection selections of the time segment. The basis for this is that the Output easier according to the smallest number of entries at the beginning connect is as in the last selection of each time segment. On the other hand the criterion for the selection of the input is based on the fact that the selection at least one channel on the input side of each issue for as long as possible should be left over. This way the degree of freedom in the selection not affected and the solutions for the next time segments can be simple be found.

If one finds for the selected input in step S9 more than one alternative in step S10 with the same number of connections of the selected outputs, then step S13 according to FIG. 4 selects the input that has the least number of channels has different expenses.

If steps S2 and S13 of FIG. 4 result in an equivalent time switch for various inputs and outputs as in the selection to be made according to the selection criteria in steps S2, S14, then the first available alternative is selected in step S4 and likewise in Step S11. If, according to the test in step S7, the selected alternative does not lead to a non-interrupting connection, then a recursive search must be made to solve the current time segment. The search is then carried out in such a way that step S12 cancels the selections up to the previous, previously unsteady, equivalent alternative, and then the process returns to steps S4 or S11, which select the next equivalent alternative. The new selection is checked in step S7, and if the selection is no better than any of the alternatives, then the flow returns to the previous selection situation in which the equivalent alternatives are valid. If desired, this is repeated until the solution for the time segment is found. In the worst case, all equivalent alternatives are dealt with, with the process first trying out the selection of different input-side time switches until all input alternatives have been processed. Only if this does not lead to success will the selection move to different editions. In this way, all alternatives on the input side are processed for each alternative on the output side. In the worst case, the search for a solution of the time segment requires a maximum number of (N _* N) -1 search operations.

The method described above also includes, according to FIG. 4, the treatment of an exceptional situation in step S5 before the process continues with the selection of the input in step S9. An exceptional situation can arise when the selection from a group of input or output interfaces with a lower priority is made, despite the fact that no channel was found for every associated input or output of a group with a higher priority, which is also in the valid time segment is to be connected. Such an exceptional situation is recognized in step S5, and the flow continues in step S6, in which the selection is made according to the group with higher priority of input or output, if this is the last possibility for input or output that to be connected within the current time segment. In the order used according to the invention, that is, first the output and then the input, an exceptional situation occurs after the selection of an output, but before an input is selected, as shown in FIG. 4. According to the above, the reason is that a priority group has more inputs than there are different outputs. Then the selection could be made based on the highest number of channels for one input, although the only connection option for a single channel of another input would be lost. For this purpose, the usual input selection criterion or steps S9 to S11 are bypassed and said individual channel is selected in step S6. The selection is also checked in step S7, after which the sequence proceeds in its normal sequence as above.

The basic implementation of the method according to the invention is presented above. The detailed algorithm used in the configuration calculation unit 32 ( FIG. 2) can be chosen freely, e.g. B. according to any known method, if at least the principle of periodic calculation can be carried out according to the invention.

The invention can be applied in cross connections that are one-sided or Allow data traffic to be switched on both sides. In cross connection on both sides The connections can be configured in the other direction in one direction coordinated procedures are built, for example as a mirror image. It is however, in an embodiment for cross-connection according to the inventions method according to the invention not possible to use this for a broadcast or to copy a selected signal into different output channels. To do this To allow, the cross connection must be equipped with a larger capacity will. This is realized in that an input and an output connection are reserved for a limited broadcast function. Selection blocks SE (not ) and time switch blocks TE (not shown) for each output link  are then connected to the time switches on the output side of the TST Cross connection arranged. An input channel that is intended for broadcast hen is via the room switch with said reserved output connection connected in which the output-side TST time switch defines the channels. The arrangement of the channels is then adjusted so that the said output connection the TE of the cross connection the broadcast channels through the selectors SE can receive. Then the time switch TE on the output side arranges the time segment elements associated with it in an order as they are for the transfer is needed. Alternatively, for a complete broadcast operation, it is possible to provide a double-capacity room switch, the first half the room switch capacity is used for this, according to the fiction to forward related time segments and the second Half of the capacity is used for broadcast operations. The broadcasting opera can then be used to directly link a time segment to the copy the desired time segment of the other half.

According to a further modification of the method, the desired Ver Binding arranged to secure the guidance information so that the contents of the input bekanals, which is to be backed up, is copied to two output channels, for example, one output channel is a backup for the other. First, it is checked whether there is a free time segment for the security channel in the input time switch there. If such a free time segment is found the contents of the free time segment to be saved become this copied free channel. Both channels are switched by the room switch different time switches on the output side and then closed to the outside the connections. If there is no free time segment in the input side Time switch found, then the fuse connection in the room switch switched such that the contents of the time segment at a certain Input of the room switch, whose time segment is to be saved, for two Output channels or to two different time switches and then copied to the output connections.

If the backup of the guidance information according to the 1 + 1 principle by Ver doubling of the mutual signal to be secured is solved, then each Cross connection with securing of the guidance information each a 1: N broadcast function and an N: 1 function for selecting the associated signals from N signals have in the reverse direction. Then the TST cross connection can be made accordingly the invention in the room switch on the signals for generating a fuse  Copy related signals to make a backup in the opposite direction generate and so a non-interrupting process can be guaranteed.

Referring to Fig. 5, the time segments of connections 1: N / N: 1 that are to experience a fuse are connected first and then the others. If all input and output time switches do not have them, then the priority time segments are connected via them in the normal process.

When the master information is saved on both sides, N + 1 must always be entered term time segments, of which a signal is to be secured, so that N Outputs must be copied and N save signals, one of which is selected must become an issue. So there are N + 1 issues.

The connection is established in that all N + 1 time segments on the input sei time switch for the same time period. The room switch selects one of the saved time segments as the selected output channel and copies the input-side time segment as a backup to all N Backup time segments. The time switches on the output side work as normal Time switch to expenditure. A connection configuration must be made be calculated if a quick backup of the guidance information is made should.

The method according to the invention allows an effective calculation method for the connection configuration. A new configuration can then be calculated quickly in processor 30 ( FIG. 2). This allows the implementation of a non-interrupting and synchronous cross-connection, which allows an error-free switching of the incidence matrix, with no need for double time switches in the cross-connection. The method according to the invention can also be used in cross-connections in which parts of bytes are switched in a parallel arrangement by the room switch.

The invention has been described above on the basis that input first and then the output is selected. A familiar with the state of the art Person understands that the procedure is also reversed Calculate non-breaking connections applied within periods can be selected so that the incoming connections are selected first the one and then the outgoing ones. The above period was 63 or 64 time segments, the number of bytes used during a selected one Time unit must be calculated, 63 or 64 times the number of the input side  time switch. Nevertheless, it goes without saying that other numbers of bytes can be handled in the selected time unit.

Claims (15)

1. A method for configuring a time-space-time cross connection for situations with changing requirements for cross connections, in which the cross connection is equipped with time switches (T) and room switches (S) and in which the signals from and to the cross connection ( 10 ) flow of data (1 ... N) at high speed and in serial arrangement with a logical frame structure, in which in turn the logical units to be transmitted and cross-linked consist of bytes, and in which the said configuration of the Cross connection is stored in an incidence matrix ( 31 ),
characterized in that

• - The new configuration of the cross connection for a period is determined simultaneously, each period containing a predetermined number of time segments and the connection configuration determined for each time segment is stored in a readiness incidence matrix ( 31 b), and that
• - During each period the time switch on the input side selects a byte to be connected by the room switch from the as yet unselected bytes by the room switch so that this byte can be connected to the desired output of the room switch during the period examined, whereby
• - The time switch on the output side arranges the bytes on the respective outputs of the room switch in an order that is required on the outgoing transmission connections, and that
• - The readiness incidence matrix ( 31 b) is then marked as an active incidence matrix ( 31 ) when all periods of the cross-connection have been processed at a desired time.

2. The method according to claim 1, characterized in that during the Generation of the connection configuration of the selected time unit bytes to be processed first in the order of those Time switches are selected (S1) where the number of unused bytes worked is equal to the number of unprocessed time segments. 3. The method according to any one of claims 1 or 2, characterized in that that selected during the generation of the connection configuration unit of time, the bytes to be processed in the order of the respective input-side time switches are selected (S2), where a need for connections to the other side of the room switch to those output-side time switch, which has the lowest number of conn have different inputs (S2). 4. The method according to any one of claims 1 or 2, characterized in that selected during the generation of the connection configuration unit of time the bytes to be processed for such an input side Switches are selected that have the largest number of time segments points to be associated with a particular single issue. 5. The method according to any one of claims 1 or 2, characterized in that selected during the generation of the connection configuration ten time unit, the bytes to be processed are selected such that from equivalent selection alternatives, the input is selected that the lowest number of connections to different editions (S13) points. 6. The method according to at least one of claims 3 to 5, characterized records that during the generation of the connection configuration in the selected time unit selected the respective byte to be processed that the selection criterion for the time switch on the  Output side (S2) and then also the selection criterion for the Time switch on the input side (S9) taking into account the selected output time switch fulfilled. 7. The method according to claim 1 or 2, characterized in that wäh generation of the connection configuration of the selected Time unit selected the bytes to be processed in that order (S2), which result from the respective time switches on the output side results in the need for connections to the other side of the room switch to the input-side time switch that has the lowest Number of connections from different editions. 8. The method according to claim 1 or 2, characterized in that wäh generation of the connection configuration of the selected Unit of time the bytes to be processed for such an output side Switch that has the highest number of time segments Connected to a particular single input. 9. The method according to claim 1 or 2, characterized in that wäh generation of the connection configuration of the selected Unit of time the bytes to be processed are selected so that at equal valuable selection alternatives, the edition is selected that corresponds to the ge has the least number of connections to different inputs (S13). 10. A method for implementing the connection that is required to secure the routing information in a digital cross-connection, using a method according to claims 1 to 9, characterized in that the input byte, which is to be protected, is copied onto two output bytes , in which

• - First, a free time segment for the backup byte is searched for in the time switch on the input side, and if a free time segment was found, the contents of the byte to be backed up are copied to different time switches via the room switch, or
• - If no free time segment is found in the time switch on the input side, the backup connection in the Raumumschal ter is established such that the contents of the time segment to be saved in some of its outputs is copied to two outputs.

11. A procedure to implement the connection to secure the Guiding information is needed in a digital cross-connection where ensuring the guidance information in a cross connection both as a 1: N broadcast function and an N: 1 selection function is implemented under Use of a method according to claims 1 to 10 or one other method of calculating the connections, characterized in that in the time switches on the input side, both the time segments, the 1: N to be broadcast, as well as all N time segments of the selection radio tion, all of which always have different time switches on the input side are bound, are connected to the same time segment, and that in the Room switch both the 1: N broadcast to all N time segments of the Selection functions using the room switcher with the outgoing Connections of the broadcasting time segments are connected as well Selection of the desired time units from the N time segments of the off functions for the selected time switches on the output side to be led. 12. A time-space-time cross-connection for observing the requirements for the cross-connection in changing situations, the cross-connection being equipped with time switches (T) and room switches (S), and the signals coming to the cross-connection ( 10 ) and depart from it, consist of high-speed serial data streams (1 ... N) which have a logical frame structure in which the logical units to be transmitted and to be connected consist of bytes, and the respective configuration of the cross connection in one stored incidence matrix (31), characterized in that the new connection configuration is adapted in that it is calculated the processor in a configuration calculating unit (32) which controls the cross connection, and that this is stored in a standby incidence matrix (31 b), wherein the new connection configuration is activated synchronized, controlled by a major ch the cross connection continues signal. 13. A cross connection according to claim 12, characterized in that an incoming connection and an outgoing connection in the room switch for the use of a limited broadcast function are reserved, the input byte intended for broadcasting via the Room switch at a selected time segment of the said reser fourth outgoing connection is copied, whose time segments by means of a selection group (SE) is selected behind the cross connection is added and with the respective outgoing connection via a Time switch group (TE) is connected to the cross connection is added. 14. A cross connection according to claim 12, characterized in that the room switcher with a double capacity for a complete Broadcast function is equipped, the first half of the capacity of the Room switch is used to connect bytes, which accordingly of the method according to any one of the preceding claims 1 to 6 were chosen, and being the second half of the capacity of the room switch for broadcast connections according to the procedure of any one of the preceding claims 1 to 6 is used. 15. The use of a cross connection according to one of the preceding Requirements for the cross-connection of transport modules (STM-N) a syn chronic digital hierarchy, or for the cross-connection of a plesiochroni transmission system.