DE1167910B - Time division multiplex switching system with a four-wire multiplex bus - Google Patents

Description

Time division multiplex switching system with a four-wire multiplex bus The invention relates to time division multiplex switching systems for telecommunications, in particular telephone systems, d. H. on switching systems in which the messages to be exchanged for each individual subscriber individual pulse sequences are modulated, which are offset from one another and are therefore nested in one another in terms of time can be combined on multiplex rails, thus allowing multiple use is made possible by connection paths. In particular, the invention relates to such time-division switching systems, which each have a four-wire multiplex bus have over which both the connections of the relevant switching system incoming as well as outgoing traffic from connections of the relevant switching system to be led.

In such switching systems there is a need; as well as Connections between the individual connections of such a switching system as well as connections between lines leading to various such switching systems belong to bring about. This can also be spatially direct neighboring switching systems act. The number of participants attending a single Time-division multiplexing system can be connected is because of this that, for various technical reasons, limits the number of pulse phases within due to the frequency bandwidth of the individual time-bundled transmission channels given sampling period and thus the number of time-bundled channels of a such a time-division switching system has an upper limit. In the presence A larger number of participants is therefore required in a switching system instead of a single large time division multiple switching system, several smaller ones Provide time-division switching systems that are spatially immediately adjacent and cooperate with one another via a suitable switching device can. A circuit arrangement designed particularly expediently for such cooperation has already been proposed. Such a circuit arrangement to which various Time division switching systems can be connected, not only enables Connections between connecting lines of such different switching systems, but, with the help of a special time division multiplex switching system Speech energy storage or other signal energy storage instead of participants, which is also connected to said circuit arrangement, also connections between connecting lines of one and the same switching system.

However, under certain circumstances it may also be desirable within a Establish time division multiplex switching system connections between two connecting lines to be able to do so without the need for special central facilities such as this in one special time division multiplex switching system combined speech energy storage should be taken to help. This can e.g. B. then be the case if to the mentioned circuit arrangement via which the various time division multiplex switching systems of an office work together, at all only switching systems with participants or other connection lines leading offices are connected and therefore the possibility of making use of those connected to a special switching system Speech energy storage is not even given.

A time division multiplex switching system is already known per se, which allows the production between two of its connecting lines without this would require special facilities. This time division switching system has a four-wire multiplex rail, on each of which the voice line is connected of the calling subscriber involved in a connection and the hearing aid of the called subscriber and on their other line the voice line of the called subscriber involved in the relevant connection and the audio line of the calling subscriber is switched on with the help of so-called modulators are. However, this known time-division switching system cannot work with others To cooperate with time division switching systems; its connecting lines Rather, they can only be used with other connecting lines of the same switching system get connected.

Furthermore, time division switching systems are each with one Four-wire multiplex rail known jointly for outgoing and incoming traffic, which also include connections between participants in different time division multiplex switching systems can be brought about, with the help of so-called modulators or with the help of so-called interconnection cells, which gate circuits included, through which the multiplex rails of two different switching systems are periodically connected so that the output of a multiplex rail to the Input of the other multiplex rail and vice versa is connected while synchronously for this purpose, the subscribers concerned are periodically connected to their multiplex rails will. In these known time division switching systems, however, connections between subscribers of one and the same time division multiplex switching system that are involved periodically connected to their multiplex rail at different times are made with the help of group-owned facilities, e.g. B. with Using low-frequency connection sets, including special demodulators and modulators are required, or with the help of so-called built-up with an RC element Phase changers, each of which also includes special connection switches and funds whose control are required.

The well-known time-division switching systems that are used for both connections two of their connecting lines with each other as well as for connections of one of their Connection lines suitable with a connection line of another switching system are, with connections between connecting lines of different time division multiplex switching systems are performed via a circuit arrangement in the form of a coupling matrix, which with Help from lying, so to speak, in the intersection points of two multiplex rails Connection switch interconnects the various time-division switching systems connects, so require a special effort for connections within the Switching system: There must be special switching system-specific arrangements such as Low-frequency connection sets or the phase changers mentioned are provided, to connections between connecting lines of one and the same switching system to be able to bring about, whereby there is still another effort for each pulsed connection of these special devices to the multiplex rail of the relevant switching system results. You can also use the coupling matrix each provide a special crosspoint through which to establish a connection a multiplex rail between two subscribers in the same switching system. for outgoing traffic with a multiplex rail for incoming traffic of the same Switching system can be connected; thus the additional effort for such connections are not eliminated, but merely relocated.

The invention now shows a way as a time division switching system with a four-wire multiplex rail is particularly useful to make without special effort both connections between two of his connecting lines with each other as well as - with the help of a suitable coupling circuit arrangement - Connections between one of its connecting lines and a connecting line of a to enable other switching system.

The invention thus relates to a time division multiplex switching system with four-wire connection lines for incoming and / or outgoing Traffic, each periodically pulsed with the help of time channel switches one in turn on multiplex rails of further time division multiplex switching systems connectable multiplex rail can be connected in a four-wire manner; this Time division multiplex switching system is characterized in that the multiplex bus consisting of two four-wire partial rails for incoming traffic and for outgoing traffic is that the line of one sub-rail, to the transmission lines of the transmission lines that transmit speech energy from the connections Four-wire connection lines can be connected to that line of the other partial rail to which the speech energy transmitted to the connections Receiving lines of the four-wire connecting lines can be connected, connected and that two each have an output line of the multiplex rail and an input line the lines forming the multiplex rail, the two lines of the partial rails the receiving lines of the Four-wire connection lines can be connected. with a switch-through network for the connection of connection lines of the time division multiplex switching system with connection lines connect further time division multiplex switching systems.

The time division switching system according to the invention permits the establishment of connections between two of its connecting lines, without the special switching system's own to be switched on by means of special switches Facilities would have to be used and without the need for a circuit arrangement for establishing connections between connecting lines of different switching systems, as already proposed, also for the production of such compounds between connecting lines of the relevant time division multiplex switching system itself would have to be used. The time division switching system according to the invention is particularly advantageous where different connection lines already exist can only be used for outgoing or incoming traffic, as is often the case for trunk lines, d. H. for connecting lines leading to other offices, the Case is. However, connection lines to the time division multiplex switching system can also be used without further ado connected, which differ from case to case for outgoing and incoming Traffic are used and then according to the respective direction of the connection establishment to one or the other rail of the multiplex rail of the time division multiplex switching system are to be switched on according to the invention. In the case of connecting lines of this type, it can in turn are trunk lines or lines that lead to operator stations to lead, which are connected to the relevant time division switching system and which z. B. to set up exchange connections to the relevant time division switching system connected trunk lines must be interconnectable. The time division switching system according to the invention can then with advantage in one of several time division switching systems, are connected to each participant, comprehensive switching system as special time division multiplex switching system is used, which is used for processing of connections between the subscribers of the relevant switching system and serves other offices; In addition, it can also be used to handle connections within the individual remaining time division multiplex switching systems 'to' each Participants are connected, are used, for which purpose it is according to further refinement of the invention is supplemented by pairs of speech energy stores connected to the two above, one output line or one input line of the multiplex rail forming lines in each case with the help of time channel switches periodically in pulses can be switched on. In this form, the time division switching system according to of the invention optionally also to supplement the connection options in a larger switching system can be used in which, in addition to the various Time division multiplex switching systems to which subscribers are connected, already a special time division multiplex switching system with speech energy storage instead of subscribers or with connecting lines leading to other offices may be.

Regardless of its particular use, the time division switching system provides according to the invention the possibility of both connections between one of its connecting lines and a connection line of a further time division multiplex switching system than also for connections between two of its connecting lines at a central point make a damping compensation; for this purpose, according to a further embodiment of the Invention in the two connections in each case that line of a partial rail, to the transmission lines transmitting the speech energy from the connections of the four-wire connection lines are connected to that line of the other partial rail to which the speech energy transmitted to the connections Receiving lines of the four-wire connection lines are connected, attenuation compensation devices inserted, with such a damping compensation device during each speech phase, to which a connection line is connected to the associated multiplex sub-rail is, by one of the line attenuation of the connection line in question Control signal can be controlled in their attenuation or gain.

The invention will now be explained in more detail using an exemplary embodiment.

In the drawing, a time division multiplex switching system according to the invention is shown in extracts to the extent necessary for an understanding of the invention. In this switching system, connecting lines, such as the connecting lines Lg, L, Lk, are connected in a four-wire manner to corresponding multiple points, each of which characterizes a certain type of service; these connecting lines can, for. B. lead to other offices or possibly also to participants or operator stations. It is assumed here that the connecting lines Lg are only used in outgoing traffic and the connecting lines Lk are only used in incoming traffic, while the connecting lines L can be used in both incoming and outgoing traffic. Via the controllable time channel switch ZSg or ZSk, the connection lines to the multiplex bus M of the time division multiplex switching system can be connected periodically in pulses.

The multiplex rail M of the time division multiplex switching system consists of the two sub-rails Mk and Mg, of which the sub-rail Mk is used for the traffic arriving via connecting lines of the time division multiplex switching system and the sub-rail Mg for the outgoing traffic via connecting lines of the time division multiplex switching system. The two partial rails Mk and Mg each have a line Mkk or Mgk, to which the transmission lines Lkk, LAkk or LBgk, Lgk of the four-wire connection lines Lk, L, Lg, which transmit speech energy from the connections, are connected to the four-wire connection lines Lk, L, Lg with the aid of the time channel switch ZSk or ZSg are connected, and one line Mkg or Mgg, to which the receiving lines Lgg, LAgg or LBkg, Lkg of the four-wire connecting lines Lg; L, Lk are switched on. The line Mkk, to which the transmission lines Lkk, LAkk of the four-wire connection lines Lk, L used in incoming traffic, which transmit speech energy from the connections, are connected, is connected via the amplifier VA k to the line Mgg, to which the lines to the connections The receiving lines Lgg, LAgg which transmit speech energy and the connection lines Lg, L used in the outgoing traffic are connected; Likewise, the line Mgk, to which the transmission lines Lgk, LBgk of the connection lines Lg, L used in outgoing traffic, which transmit speech energy from the connections, are connected, is connected via the amplifier VBk to the line Mkg, to which the speech energy transmitted to the connections is connected Receiving lines Lkg, LBkg of the connecting lines Lk, L used in incoming traffic are connected. In addition, the two lines MA and MB are connected to the two lines Mgg and Mkg of the two partial rails Mg and Mk, one of which forms the output line and the other the input line of the multiplex rail M depending on the traffic direction (connection establishment direction); Via the two lines MA and MB , the multiplex bus M of the time division multiplex switching system is connected to the coupling network KF, which enables connections to be made between connections of the time division multiplex switching system and connection lines of other time division multiplex switching systems connected to the coupling network KF, which are definitely after a other principle can be constructed. For this purpose, the coupling network KF has a coupling point KP with a corresponding number of coupling point contacts correspondingly connected to the lines MA and MB of the multiplex bus M for each pair of multiplex rails to be connected to one another. Such a coupling network, to which several other time division multiplex switching systems can be connected, enables not only connections between connection lines of such different switching systems, but possibly also connections between connection lines of a single such other switching system. Such a coupling network has already been proposed and is not the subject of the invention.

The connecting lines Lg, which are only used in outgoing traffic, are each connected to the partial rail Mg for outgoing traffic by means of a time channel switch ZSg and the connecting lines Lk, which are only used in incoming traffic, are each connected to the partial rail Mk for incoming traffic by means of a time channel switch ZSk Traffic can be switched on. The connection lines L, which can be used both in incoming traffic and in outgoing traffic, can be connected either by means of a first time channel switch ZSg to the partial rail Mg for outgoing traffic or by means of a second time channel switch ZSk to the partial rail Mk for incoming traffic. Finally, pairs of speech energy stores CA, CB can be connected to the two lines MA and MB of the multiplex rail M, which each form an output line and an input line of the multiplex rail M, by means of the time channel switch ZSs, which will be discussed in more detail below.

All time channel switches are controlled by control pulses, which are supplied with the help of circulating memories. In the time division switching system according to the invention, two circulating memories are used, denoted USk and USg. In the circulating memory USk, the call numbers of connections that are involved as calling subscribers in a connection circulate in coded form, in which the associated connection line, viewed from the multiplex rail M, is used with regard to the direction of the connection setup in the incoming traffic; The call numbers of connections involved in a connection in which the associated connection line is used with regard to the direction of the connection setup in the outgoing traffic circulate in a corresponding manner in the un-run memory USg. The call numbers in coded form are referred to below as addresses. The so-called control decoders Dk and Dg are connected to the outputs of the circulating memory USk and USg. The control decoder Dk has as many outputs as there are usable connection lines in the incoming traffic within the time division multiplex switching system, and the control decoder Dg has as many outputs as there are usable connection lines in the outgoing traffic. Each of these outputs is assigned to a specific connection. The control inputs of the time channel switch ZSk, which are connected to the partial rail Mk for incoming traffic, are each connected to an output of the control decoder Dk, while the control inputs of the time channel switch ZSg leading to the partial rail Mg for outgoing traffic are each connected to an output of the control decoder Dg are. Each time channel switch ZSs, via which a pair of speech energy stores CA, CB can be connected to the two lines MA, MB of the multiplex rail M , has its control input connected both to an output of the control decoder Dk and to an output of the control decoder Dg. When the address of a connection is fed to a control decoder, it emits a pulse at the output that is assigned to this connection. This pulse is used to control the time channel switch assigned to the respective connection so that it is closed in pulses.

A connection between two connection lines of the time division multiplex switching system, e.g. B. between the connecting lines Lk and L, now comes about in the following way. With the aid of the circulating memory USk, the time channel switch ZSk of the connection line Lk is periodically closed in pulses, so that the connection line Lk is periodically connected to the partial rail Mk of the multiplex rail M. The control pulse causing this type of closure has a certain phase position which differs from the phase positions of control pulses which are assigned to other connecting lines of the same switching system that are also used in incoming traffic. Synchronously with the actuation of the time channel switch ZSk assigned to the connection line Lk mentioned, the time channel switch ZSg of the connection line L is now periodically closed in pulses with the aid of the circulating memory USg. This results in a pulsed connection between the connecting line Lk and the connecting line L, with signal energy in one direction from the connecting line Lk via its line Lkk, the line Mkk of the partial rail Mk and the line Mgg of the partial rail Mg to the line LAgg and thus is transmitted to the line LA of the connecting line L, while in the opposite direction signal energy is transmitted from the connecting line L via its lines LB and LBgk, via the line Mgk of the partial rail Mg and the line Mkg of the partial rail Mk to the line Lkg of the connecting line Lk is transferred out. Such connections in each case between two connection lines of the time division multiplex switching system can thus be established without the need to use special equipment to be connected by means of special switches and without the coupling network KF, which is used to establish connections between the illustrated time division multiplex switching system and other time division multiplexing systems Switching systems as well as for establishing connections within the individual remaining time division multiplex switching systems would also have to be used to establish connections between two connecting lines of the illustrated time division multiplex switching system. It is therefore not necessary in the switching system, which includes all switching systems connected to the coupling network KF, to provide special time-division switching systems with speech energy stores instead of subscribers for establishing connections between two connecting lines of the time-division switching system shown. Conversely, however, as will be explained in more detail below, the time division multiplex switching system according to the invention can be used to handle connections between two subscribers of one of the other time division multiplex switching systems connected to the coupling network KF in which such connections are made between connecting lines of one and the same switching system are to be processed via the coupling matrix KF with the aid of speech energy stores, as has already been described elsewhere.

As already stated in the introduction, in addition to connections between individual connections of the time division multiplex switching system shown, connections between a connection line of the time division multiplex switching system according to the invention and a z. B. to a subscriber leading connection line of another time division multiplex switching system, which is connected to the coupling network KF, can be brought about. Such a connection between a connection line of the illustrated time division switching system according to the invention, e.g. B. the connection line L, and a subscriber in a different time division multiplex switching system, not shown, now comes about in the following way. It is assumed that the connection line L is used in the incoming traffic for this connection, so that the called subscriber is in the other time division multiplex switching system. In the time division multiplex switching system according to the invention, the time channel switch ZSk of the connection line L is therefore periodically closed in pulses, so that the connection line L is periodically connected to the partial rail Mk. The control pulse causing this type of closure in turn has a certain phase position which differs from the phase position control pulses which are possibly assigned to other connection lines of the same time-division multiplex switching system. Synchronously with the actuation of the mentioned connection line L associated time channel switch ZSk is in the coupling point KP, which in the coupling network KF as it were as a crossover point of the multiplex rail M of the illustrated time division multiplex switching system according to the invention with the multiplex rail of the further time division multiplex switching system, not shown, to which the called subscriber is connected , is to be seen, a pair of crosspoint contacts periodically closed in pulses, so that the output line of the multiplex bus of the time division multiplex switching system according to the invention with the input line of the multiplex bus of the other time division multiplex switching system and vice versa its output line with the input line of the multiplex bus M of the time division multiplex switching system according to the invention connected is. When here, for example, considered connection in which the connecting line L is used in the incoming traffic, and consequently their time channel switch ZSK is closed periodically pulsed manner, the line MA leads the multiplex rail M transmitted crosstalk energy from the connection line L forth, and so serves as the starting line while the Line MB which leads to the connection line L to be transmitted speech energy and therefore serves as an input line. If, on the other hand, the connection line L is used in outgoing traffic, the two lines MA and MB - as well as the two lines LA and LB of the connection line L - are used in the opposite direction of transmission in the illustrated time division multiplex switching system, so that the Line MB serves as an output line and line MA serves as an input line. By closing the associated pair of crosspoint contacts, there is a pulsed connection between the multiplex bus M of the illustrated time-division switching system and the multiplexing bus of the other time-division multiplex switching system. In this other time-division multiplex switching system, the address of the called subscriber now circulates in its circulating memory, in such a way that the resulting control pulse for the time channel switch belonging to this called subscriber has the same phase position as the control pulse that controls the time channel switch ZSk of the connecting line L. controls. In this way, the time channel switch ZSk of the calling connection line L, the crosspoint contacts of the crosspoint located at the crossing point and the time channel switch of the called subscriber connected to the other time division multiplex switching system are closed at the same time, whereby the desired connection between the connection line L and - the called subscriber came about.

As already mentioned above, the coupling network KF, with the appropriate design, as has already been proposed, enables not only connections between connection lines of different switching systems, but also connections between connection lines of one and the same switching system with the aid of a time-division multiplex switching system with speech energy storage instead of subscribers. In an office in which different time-division multiplex switching systems with connection lines leading to subscribers or other offices work together via such a coupling network, it may be inexpedient for traffic-theoretical considerations to provide a special time-division switching system of its own which only uses speech energy storage instead of Has participants. In such a switching office, the time division multiplex switching system according to the invention can now be used with advantage as a special time division multiplex switching system, which also allows the handling of connections within the individual remaining time division multiplex switching systems. To this end switching system time multiplex the speech energy storage CA, CB are provided in pairs in the illustrated that the multiplex rail M are each connectable using the time channel switches ZSŚ to leading to the switching network KF lines AM, MB. These speech energy stores can then be used to establish connections between two subscribers of another time division multiplex switching system.

For such a connection, two control pulses with different phase positions are required. In the circulating memory of the other time division multiplex switching system, not shown, to which the relevant two subscribers to be connected are connected, the addresses of these two subscribers circulate with a time offset from one another; Via the associated time channel switch, the subscribers in question are therefore connected periodically in pulses, but at different times, to the multiplex rail of the time division multiplex switching system in question. In order to bring about the desired connection, at the point of intersection between the multiplex rail of the time division multiplex switching system in question and the multiplex rail M of the time division multiplex switching system according to the invention, a coupling network KF coupling point KP is closed at one point in time through which the one Line (voice line) of the multiplex rail of the foreign time division multiplex switching system z. B. with the line MA of the multiplex bus M of the time division multiplex switching system according to the invention and the other line (audio line) of the foreign time division multiplex switching system is connected to the line MB of the multiplex bus M; at the other time, another coupling point contact pair is closed at the respective coupling point, through which the line MA of the multiplex bus M of the time division multiplex switching system according to the invention with the second line (audio line) of the foreign time division multiplex switching system and its first line (voice line) with the Line MB of the multiplex rail M is connected. Just as with a connection routed via the lines MA and MB of the multiplex rail M between a subscriber of another switching system and a connection line L that can be used in outgoing or incoming traffic, the line MA of the illustrated time division multiplex switching system serves as an input line and the other time as the output line of the multiplex rail, while conversely the line MB serves one time as an output line and the other time as an input line, depending on whether the connection in which a connection of the time division multiplex switching system according to the invention is involved leads to it or from it this, ie depending on whether the traffic is outgoing to this connection or traffic arriving from this connection. The address of this connection now runs for the processing of a connection between two subscribers and the same foreign time division multiplex switching system in the circulating memories of the time division switching system according to the invention, the address of the same speech; energy storage pair CA, CB twice, in such a way that two control pulses for closing the associated time channel switch ZSs are supplied, which are in phase with the two control pulses supplied for this connection in the external time division multiplex switching system. The respectively used both speech energy storage CA and CB now bridged in each case in a known manner, the periods that lie between two closures of the associated the respective subscribers in the foreign mediation system, two time channel switch, at which a pulse phase of a speech energy storage CA z. B. with the voice line of the calling participant and the voice energy store CB with the hearing line of the calling participant and for the other pulse phase the speech energy store CA with the hearing line of the called participant and the speech energy store CB with the voice line of the called participant is pulsed, so that an exchange von Spreche.iergie takes place between the participants involved. These processes are repeated periodically with the circulation period of an address circulating in a circulating memory. This results in the intended connection between two subscribers of a foreign time division multiplex switching system, which is connected to the coupling network KF, with the aid of pairs of speech energy stores provided in the time division multiplex switching system according to the invention.

The time-division multiplex switching system according to the invention can therefore be used in a switching system with several switching systems which only have connection lines leading to subscribers or also to other offices and which work together via a suitable coupling network KF, whereby one and the same switching system is connected to establish connections between two connection lines Speech energy storage connected to a special switching system must be used as the only special time-division multiplex switching system both for handling connections between a connection line of one of the other switching systems and a connection line of this particular switching system and for handling connections between connection lines of one and the same external switching system , since the time division switching system according to the invention, although such energy storage for establishing connections between en subscribers has one and the same external switching system, but itself does not require any such speech energy storage, which may be combined in a special switching system, to handle its own internal traffic. The time-division switching system according to the invention still offers the possibility of making attenuation compensation both for connections between one of its connection lines Lg, L, Lk and a connection line of a further time-division switching system and for connections between two of its connection lines at a central point. In a further embodiment of the time-division switching system according to the invention, the two connections of the two partial rails Mk and Mg, ie the connection of the line Mkk of the partial rail Mk with the line Mgg of the partial rail Mg and the connection of the line Mgk of the partial rail Mg with the line Mkg of the partial rail Mk, two damping compensation devices VAk and VBk are inserted. The attenuation compensation devices VAk and VBk make it possible to undertake an attenuation compensation for the speech signals of all speech paths routed via the lines Mkk and Mgk of the partial rails Mk and Mg at a central point. Such a damping compensation device, such as. B. the attenuation compensation device VBk, during each speech phase, to which a connection line, such. B. the connection line Lg, is connected to the associated rail, so the partial rail Mg in the example, can be controlled by a control signal corresponding to the line attenuation of the relevant connection line Lg in their attenuation or gain. This makes it possible to determine the attenuation or gain of the attenuation compensation devices inserted in the multiplex rail M, ie for each speech phase, as required by the line attenuation of the connection line connected to the relevant partial rail for this speech phase. In this way, the same line attenuation can be achieved for each speech path, regardless of the type and length of the line used for this purpose, without having to insert a specially adapted attenuation compensation device into each connection line. Such attenuation compensation devices, which can be controlled in their attenuation or amplification level by a control signal corresponding to the line attenuation of the connection line in question, have already been proposed; it should therefore be superfluous to go into more detail on the design of such damping compensation devices, especially since this is not necessary to understand the structure and function of the time division multiplex switching system according to the invention.

Claims (6)

Claims: 1. Time-division switching system for telecommunications, in particular telephone systems with four-wire-connected connection lines for incoming and / or outgoing traffic, which can be connected in a four-wire manner with the help of time channel switches periodically in pulses to a multiplex rail that can be connected to multiplex rails of further time-division switching systems, since -characterized in that the multiplex rail (M) consists of two four-wire formed sub-rails (Mk and Mg) for incoming traffic and for outgoing traffic, that in each case that line (Mkk or Mgk) of one sub-rail (Mk or Mg) is on the transmission lines (Lkk, LAkk or LBgk, Lgk) of the four-wire connection lines (Lk, L, Lg) transmitting speech energy from the connections can be connected to that line (Mgg or Mkg) of the other partial rail (Mg or Mk), to the receiving line transmitting the speech energy to the connections lines (Lgg, LAgg or LBkg, Lkg) of the four-wire connection lines (Lg, L, Lk) can be connected, and that two lines (MA, MB) each forming an output line of the multiplex rail or an input line of the multiplex rail, the two lines (Mgg, Mgk) of the partial rails (Mg, Mk) to the receiving lines (Lgg, LAgg or LBkg; Lkg) of the four-wire connection lines (Lg, L, Lk) can be connected to a through-connection network (KF) for connecting connection lines (Lk, L, Lg) of the time-division switching system with connection lines of further time-division switching systems. 2. Time-division multiplex switching system according to claim 1, characterized in that in the two connections that line (Mkk or Mgk) of a partial rail (Mk or Mg) to which the respective transmission lines (Lkk, LAkk or LBgk, Lgk) of the four-wire connection lines (Lk, L, Lg) can be connected to that line (Mgg or Mkg) of the other partial rail (Mg or Mk) to which the receiving lines ( Lgg, LAgg or LBkg, Lkg) of the four-wire connection lines (Lg, L, Lk) can be connected, attenuation compensation devices (VAk, VBk) are inserted. 3. Time division multiplex switching system according to claim 2, characterized in that the attenuation compensation devices (VAk, VBk) during each speech phase to which a connection line (Lk, L, Lg) is connected to the associated rail (Mk, Mg) by one of the Line attenuation of the relevant connection line (Lk, L, Lg) corresponding control signal can be controlled in their attenuation level. ' 4. Time division multiplex - switching system according to one of the preceding claims, characterized in that the two lines (MA, MB) forming an output line or an input line of the multiplex rail with the aid of time channel switches pairs of speech energy stores (CA, CB) can be switched on periodically in pulses . 5. Time division multiplex switching system according to one of the preceding claims, characterized by two circular memories (USg, USk), in one of which (USg) the addresses of time channel switches (ZSg) to be closed in pulses, represented by code characters, through which the connection lines used in outgoing traffic ( Lg, L) can be connected to the associated sub-rail (Mg), circulate as control commands for their actuation, and in the other (USk) the addresses of time channel switches (ZSk) to be closed in pulses, which are used in the incoming traffic and which are represented by code characters (Lk, L) can be connected to the associated partial rail (Mk), circulate as control commands for their actuation. 6. Time division multiplex switching system according to claim 5, characterized in that in both circulating memories (USg, USk) the addresses represented by code characters of time channel switches (ZSs) to be closed in pulses, through which the one and the same time division multiplex switching system is used for connections between two connecting lines Speech energy storage pairs (CA, CB) can be connected to the two lines (MA, MB) which each form an output line or an input line of the multiplex rail (M), as control commands for their actuation are staggered in time. Documents considered: German Patent No. 947 249; British Patent No. 856 732.