DE3136630C2 - - Google Patents

Description

The invention relates to a method and a circuit arrangement for setting the transmission times for the transmission of information signals when there is a connection from one first line connection device to a second line connection closing device of a telecommunications switching system, in which those which feed or discharge the information signals Line circuits connected line connection devices via a clock-controlled directional ring ring system are interconnected on which the information signals are transmitted according to a time division principle.

For the transmission of information signals between two bigen line connection devices depending on the direction driven ring ring working on a time-division principle tion system, it is necessary to take information signals giving line connection device when establishing a connection such broadcasting times, which are also referred to below as broadcasting times are designated to assign that receipt of information signals in a selected line connection device is ensured.

A method for transmitting messages in a time-division multiplex system with a transmission arranged in a loop is already known (DE-OS 26 59 533). With this method, a plurality of subscriber stations and a clock generator are connected directly to a loop-shaped, time-dependent line which is operated in a direction-dependent manner. The clock generator transmits periodically for the synchronization of the individual subscriber stations serving synchronization blocks, the time from which is divided into a number of time channels. Of these time channels, two free time channels i and i + a are occupied for a connection between two subscriber stations by the calling subscriber station, where a indicates the loop runtime as an integer multiple of the duration of a time channel. In the time channel i , signaling blocks and message blocks serving for establishing the connection are transmitted from the calling subscriber station to the called subscriber station when there is an existing connection. This time channel i is also used by the called subscriber station for sending signaling blocks and message blocks which are taken over by the time division line after the clock generator has been run by the calling subscriber station in time channel i + a .

The invention is based on the object to show a way conditions, as in the case of a telecommunications switching system named in a relatively simple way in an information Signaling line connection device such transmission time could be determined that the receipt of information guarantee signals in a selected line connection device is accomplished.

The above problem is solved in a process ren of the type mentioned in the present invention in that all lines connected to the loop system connection facilities a common time subject of cyclical like catches up in successive first time-division multiplex frames occurring time slots for information signal reception for ver is that in a second, with the repetition frequency of Time slots repeating time-division multiplex frames each of the connected to the line connection devices Line circuits a specific time slot in the respective Time slot for the information signal recording is assigned that in the respective line connection device using a this associated address information and based on a for the line connection provided for the information signal reception direction determining address information the transmission time to the line provided for the information signal recording Connection device is determined that this transmission time is subtracted from the duration of the first time-division multiplex frame  and that according to the difference determined in this way within of the respective first time-division multiplex frame in relation to its The beginning of the frame in question and the associated broadcasting time slot Broadcast time slot can be defined.

The invention has the advantage that due to the taking information transmitted over the loop system signals through all line connection devices in one and the same time slot within each first time division multiplex mens the transmission time slots for the respective signal transmission in the individual line connection devices with a low Control effort can be determined. Use one and the same time slot for the recording of information signals len through all line connection equipment brings about it the advantage of a simple clock control for the ring pipe system with itself.

This makes the respective transmission time expedient determines that first the difference between the infor line signal to be included numbers assigned to directions is formed, which are those in the Ring line system contained line connection devices number consecutively, and then this difference with a predetermined amount of time is multiplied by the duration the signal transmission between two in the loop system indirectly indicated adjacent line connection devices becomes. This has the advantage of a simple determination of the Transmission time with itself.

It is useful to carry out the method according to the invention moderate to use a circuit arrangement, characterized thereby is that each line connection device has a transmission Control circuit contains, based on the respective line connection device determining address information and on the basis one a Lei provided for information signal recording address device determining the address information Transmission time before that for the information signal recording seen line connection device determines this transfer  time of the duration of a first time division sub trahts, according to the difference thus determined, the inner half of the respective first time-division multiplex frame based on whose beginning of the relevant time slot and the associated transmission time slot determined and information regarding this Timeslot and associated timeslot during the Duration of a connection. This has the advantage that the Determination of the assigned transmission time slots within the respective leaden line connection device can be done and that corresponding central facilities within the ring line systems can be omitted.

The transmission control circuit preferably contains a microcompu ter. This has the advantage of low circuit technology the effort for the transmission control circuit.

The circuit arrangement is expediently designed such that with the transmit control circuit of each line terminal a first memory is connected, which is used to store the specify the respective transmission time slots and transmission time slots Control variables in the line circuits individually associated Memory cells that the relevant transmission control circuit a counter arrangement is assigned, which corresponds with corresponding counter arrangements of all other line connections directions associated transmission control circuits in such a synchronous manner is operated that they are within each first time division frame your counters in the relevant time timeslots and time slots contained in the multiplex frame net, and that with the output of the relevant transmission tax circuit associated meter arrangement and with the output of the associated first memory is connected to a comparator when determining a match between the respective Counter position of the counter arrangement and one of those concerned control values stored in the first memory trigger signal for triggering the transmission of information signals from the line circuit in question. This has the advantage that for the storage of the information regarding the transmission time slots and transmission time slots with single  Lich memory can be used, in which the An number of memory cells equal to the number on one line Connection device connected line circuit is, and that to process a send a relatively small circuit complexity is required.

The respective transmission control circuit is expediently one second memory downstream; the one of the number of belonging corresponding number of memory cells for the temporary storage of information signals to be sent len and which is based on the release of a trigger signal from the associated comparator for the delivery of cached Information signals can be effectively controlled. This gives the advantage is that for the sometimes desired snack of information signals to be sent out only Memory is required that is one of the number of associated Line circuits corresponding number of memory cells points.

The one with the respective transmission control circuit is preferred connected first memories connected to an output register, which at the time of sending out information signals Information for a next broadcast time slot and an associated one Takes over the transmission time slot from the relevant first memory, which then ver with the meter reading of the associated meter arrangement are comparable. This ensures that the transmission of Information signals at a given transmission time slot hesitates to run.

In the following the invention with reference to drawings example described in more detail.

Fig. 1 shows in a block diagram a ring line system in which the invention is applied.

Fig. 2 shows a block diagram of the structure of a transmission control circuit.

FIGS. 3 and 4 illustrate timing diagrams for explaining the Zeitmul used for the transmission of information signals represents tiplexprinzips.

Fig. 1 shows a modularly expandable switching system to which a number of line connection devices ST 1 to STn belongs. These line connection devices are connected to one another via a direction-dependent clock-controlled ring line system LB. The individual line connection devices can be constructed in a smooth manner.

1, each line connection device contains an interface circuit LS 1 , LS 2 , LS 3 . . . LSn and a control circuit LST 1 , LST 2 , LST 3 . . . LSTn . These line connection devices are connected to line circuits T 1 to Tm representing signal transmitters or signal receivers. The interface circuits LS are synchronized via a central control circuit ZST . In Fig. 1 it is shown symbolically that the ring line system LB consists of a system of parallel lines for parallel data transmission. However, serial data transmission via a single line is also possible.

In Fig. 1, a possible circuit structure of a control circuit serving to control a transmission process LST 1 is also shown in more detail. This circuit arrangement contains a transmission control circuit SST , which is connected to the interface circuit LS 1 by means of a control output. In addition, this transmission control circuit SST is connected via lines D 1 , D 2 and D 3 to the data inputs of a first memory ZSP . This first memory ZSP is divided into three areas Z 1 , Z 2 , K un. The areas Z 1 and Z 2 are used for intermediate storage of the information regarding a time of transmission. A region K - hereinafter referred to as a chain region - marks the sequence of the memory cell processing in the regions Z 1 and Z 2 . The data outputs of said first memory are connected to inputs of an output register AReg . This output register contains areas Z 1 ', Z 2 ' and K '. There are also connections between data outputs of the memory ZSP and data inputs of the transmission control circuit SST . To address the memory cells of the memory ZSP , address inputs of the said memory are connected to data outputs of a data switch ADR 1 . Depending on a control signal on a line L 2, either address signals from lines A 1 or address signals from lines L 5 serve as input signals for this data transfer ADR 1 . The execution of write and read cycles is controlled via lines L 1 and L 4 . On the output side, the areas Z 1 'and Z 2 ' of the output register AReg are connected to data inputs of a comparator Vgl . Outputs of a counter arrangement ZSZ , which is divided into the areas ZS 1 and ZS 2 , are connected to further data inputs of the comparator Vgl . The output of the comparator Vgl is connected to an input of the transmission control circuit SST . Another control input of the transmission control circuit SST is used to receive control signals from the line circuits T 1 to Tm .

The circuit arrangement contains a second memory BSP , the data inputs of which are connected to the line circuits T 1 to Tm and the data outputs of which are connected to the inputs of a takeover register UReg . On the output side, this takeover register, which is controlled by the transmission control circuit SST , is connected to the interface circuit LS 1 . The memory cells of the second memory BSP are addressed via a data switch ADR 2 . This data switch ADR 2 is controlled via a line L 6 . Outputs of the output register (area K ') and outputs of the counter ZSZ (area ZS 2 ) are connected to the data inputs of this data switch ADR 2 . To carry out write and read cycles via a line L 3 there is a connection between the transmission control circuit SST and the second memory BSP .

In Fig. 2, a possible structure of a circuit arrangement for determining the transmission times within the transmitter control circuit SST is shown as a block diagram. Regi ster Reg 1 , Reg 2 and Reg 3 are provided on the input side of this circuit arrangement. In the register Reg 1 , address information is taken from one of the line circuits T 1 to Tm connected to the line connection device concerned. Constants are permanently stored in the registers Reg 2 and Reg 3 . On the output side, these three registers are connected to a first difference stage Diff 1 . The register Reg 3 can only be effectively controlled by a separate control from the differential stage Diff 1 , which will be discussed in more detail below. This first differential stage Diff 1 is followed by a multiplier MUL which multiplies the output values of this differential stage by a constant factor stored in a register Reg 4 . This multiplier MUL is connected to a second differential stage Diff 2 , which forms the difference between a constant value temporarily stored in a register Reg 5 and the product supplied by the multiplier. A further register Reg 6 is connected to this second differential stage Diff 2 . In addition, it is indicated by a dashed line that part of the address information from the respective line circuit T 1 to Tm is taken directly into the register Reg 6 . It should be noted here that the function of this circuit arrangement can also be easily implemented by a microcomputer.

After the structure of the circuit arrangement according to FIGS . 1 and 2 has been explained, the mode of operation of these circuit arrangements will be described below. Before, however, in connection with FIGS. 3 and 4, the transmission principle used for the transmission of information signals via the ring line system LB is explained. This principle is a two-stage time multiplex principle. The ring line system is constructed so that information signals are transmitted in sections from a line connection device to the line connection device following in the ring line system LB with the aid of bus clock pulses BT . According to the two-stage time-division multiplex principle, the periodic repetitive first time-division multiplex frame ZM , i.e. time-division multiplex frame with cyclically repeating time slots assigned to the individual line connection devices, are decisive on the ring line system LB , through synchronization signals SYN 1 , SYN 2 , SYN 3 , SYN 3, which are output by the central control device SYNn ( Fig. 3 and 4) set. Each such time-division multiplex frame ZM thus has a number of attached to the ring line system LB connected line terminal means ST corresponding number of time slots on, which include the time bins Zf 1 and ZFN and each m into a number of divided time slots ZT 1 to MDT. The number m of the relevant time slots ZT 1 to ZTm is equal to the maximum number of line circuits T 1 to Tm that can be connected to a line connection device . The time slots form a second time-division multiplex frame which is repeated periodically with the frequency of the time slots. In the present case, the time slots occur with the repetition frequency of the bus clock pulses BT .

Within each first time-division multiplex frame which is decisive on the ring line system LB , a reception time compartment given by a single time slot with its time slots, for example by the last time slot Zfn , is received for an effective reception of the information signals received by the respective line connection device in this time slot by the exploited at this connected line circuits T 1 to Tm . The time slots within the relevant time subject are permanently assigned to the line circuits T 1 to Tm connected to the respective line connection device for the reception of information signals.

The time slots and time slots to be used for the transmission of information signals from the individual line connection devices are not permanently assigned to the line connection devices concerned, but rather are only assigned to these line connection devices depending on various factors. One of these factors is given by the time span required to transmit information signals from a transmitting line connection device to a desired line connection device via the ring line system LB. Another factor is given by the fact that, taking into account the aforementioned period of time, it must be ensured that the transmitted information signals are also received by the desired receiving line connection device during the aforementioned common receive time slot. In order to take into account the temporal relationships mentioned above, the individual line connection devices in the signal transmission direction of the loop line system LB are assigned consecutive numbers which, relative to one another, provide an indication of the signal transmission time between the individual line connection devices and which correspond to the position of the line connection device in the ring line system LB. If one looks at two line connection devices, for example the numbers 16 and 18 are assigned, and it is assumed that information signals are to be transmitted from line connection device No. 16 to line connection device No. 18, the difference of 2 between the results two numbers multiplied by a time period which indicates the duration of the signal transmission between two immediately adjacent line connection devices in the ring line system, the transmission time between the line connection devices bearing these two numbers. In the present case, the transmission time is two time slot units. When transmitting information signals from the line connection device No. 18 to the line connection device No. 16, all numbers of the line connection devices lying between the two line connection devices mentioned in the signal transmission direction of the loop line system LB should be taken into account.

In order to determine the time slots actually applicable for the respective information signal transmission after determining the time slots considered above, it is now necessary to project the relevant time spans to a certain extent onto the next reception time slot common to all line connection devices. This takes place as follows: Since the duration of the respective time-division multiplex frame ZM is known, the time period calculated first is subtracted from the duration of the time-division multiplex frame under consideration. The time quantity determined in this way then determines, based on the starting point of the respective time multiplex frame, the time period or the time slot for the transmission of information signals from the line connection device under consideration, so that these information signals during the mentioned common reception time slot from the desired receiving line connection device also be included. The time slot to be used for a transmission process within a time slot results directly from the time slot which is assigned to the line circuit T 1 to Tm selected as the receiver in the relevant receive the line connection device, since this fixed assignment applies to each time slot.

In the following, the determination of the transmission times will be explained first with reference to the circuit arrangement shown in FIG. 2 and subsequently with reference to FIG. 1 the storage of the information regarding these transmission times and the sequence of a transmission process will be explained.

When establishing a connection, the transmission control circuit SST first determines the information signals assigned to it by the one of the line circuits T 1 to Tm connected to the associated line connection device and the selected receiving line connection device and the selected line circuit connected to it within the ring line system. The address information is therefore the number of the receiving line connection device and within this line connection device the number of the time slot assigned to the selected line circuit. The time slot number of the selected line circuit is transferred directly to register Reg 6 . From the number mer of the receiving line connection device, the method described above is to be derived according to the transmission time. This is done as follows: The number of the receiving line connection device is transferred to register Reg 1 . As the constant input variables for the subsequent determination, the transmission control circuit SST in register Reg 2 has the number of its own line connection device (transmitting line connection device) and in register Reg 3 the total number of numbers assigned in the loop line system LB is available. The downstream first differential stage Diff 1 now forms the difference between the number of the sending line connection device and the number of the receiving line connection device. If a negative result occurs, it means that the receiving line connection device in the signal transmission direction is behind the transmitting line connection device. In this case, register 3 is effectively controlled, so that the difference that has just been determined is now subtracted from the total number of numbers assigned in register 3 in the loop system. The result of this difference formation is multiplied in the multiplier MUL by a predetermined time variable stored in the register Reg 4 , by means of which the duration of the signal transmission between two line connection devices immediately adjacent in the ring line system is specified. It is assumed that the duration of the signal transmission between the respective adjacent line connection devices is the same. The product, which indicates the transmission time between the two selected line connection devices, is subtracted in the second difference stage Diff 2 from a time quantity representing the time span of the first time-division multiplex frame ZM (temporarily stored in register Reg 5 ). The result of this difference formation indicates the time slot based on the starting point of the time-division multiplex frame, which is to be used by the relevant line connection device for a transmission process. This information regarding the time slot to be used is then transferred to the Reg 6 register. Thus, for further processing in register Reg 6, the first part of the time slot to be used for a transmission process and the second part of the time slot to be used within the time slot are available.

The line circuits T 1 to Tm have individually assigned memory cells within the first memory ZSP for storing the information regarding the transmission times. Each memory cell is, as already mentioned above, divided so that the time slot to be used for a transmission process is stored in a first area Z 1 and the time slot to be used within the time slot is stored in a second area Z 2 . The contents of these memory cells of the first memory ZSP are read out cyclically within each first time-division multiplex frame ZM , as will be explained in the explanation of the course of a transmission process. In order to achieve fast memory access for this purpose, a further area K (chaining area) is provided in each memory cell, in which a chaining parameter which characterizes the chronological order of the memory cell processing is stored. In this exemplary embodiment, the address of the memory cell to be processed next is used as the chaining parameter. It should be noted here that each memory cell that contains current information regarding a transmission time must be included in a closed chaining, ie each of these memory cells must have a corresponding chaining parameter. As a result, the memory cell in which newly calculated information relating to a transmission time is to be stored must be inserted into an existing chain. This is done in such a way that the transmission control circuit SST switches the memory ZSP into a read mode by a control signal on the line L 2 . At the same time, the data switch ADR 1 is controlled in such a way that the address lines A 1 are softly connected to the address inputs of the memory ZSP via this data. The memory cells are then addressed in sequence, and the contents of these memory cells are transferred to the transmission control device. From the contents of the areas Z 1 and Z 2, the latter determines the memory cells in which the transmission time preceding and following with respect to the transmission time just calculated is stored. The content of the first-mentioned memory cell is changed in a subsequent write cycle (control takes place via line L 1 ) such that the address of the line circuit for which the transmission time has just been determined is now specified as the new chaining parameter. In a further write cycle, the information recorded in register Reg 6 relating to the newly calculated transmission time is stored under the address assigned to the line circuit concerned. The address of the memory cell which contains information about the subsequent transmission time mentioned is now added as the chaining parameter. The ZSP memory is now updated. When a connection is triggered, the memory cell assigned to the respective line circuit must be chained out in a corresponding manner, ie deleted from the chaining.

After the connection has been established (after the calculation of the transmission time) from one of the line circuits T 1 to Tm, information signals to be transmitted are passed to the assigned control circuit LST 1 in a clock-controlled manner. The control clock required here is derived from the output signals of the synchronously operated counter arrangement ZSZ present in all line connection devices , specifically from the area ZS 2 , from whose counter readings the time slots assigned to the connected line circuits T 1 to Tm are derived. With the transfer of the information signals mentioned to the control circuit LST 1 , the relevant line circuit T 1 to Tm emits a control signal to the associated transmission control circuit SST . On the basis of this signal, the transmission control circuit SST controls the data switch ADR 2 by a corresponding signal on the line L 6 in such a state that the current counter reading of the area ZS 2 of the counter arrangement ZSZ is present as address information at the address inputs of the second memory BSP . Thus, each connected line circuit T 1 to Tm is assigned a memory cell within the second memory BSP, which is uniquely defined by a count of the area ZS 2 mentioned, for intermediate storage of the information signals to be emitted. This memory cell assignment corresponds to the memory cell assignment within the first memory ZSP . The transfer of the relevant information signals in the memory BSP now controls the transmission control circuit SST by means of a corresponding control signal on line L 3 . The information signals buffered in this way remain in the memory BSP until the transmission time calculated for the respective line circuit T 1 to Tm .

To illustrate a transmission process with respect to a line circuit, an overview of the time sequences is first considered. To initiate such a transmission process, the content of the memory cells of the two memories ZSP and BSP assigned to the line circuit concerned is first read out in a read cycle. The content of the relevant memory cell of the first memory ZSP is transferred to the output register AReg and the content of the relevant memory cell of the second memory BSP is transferred to the transfer register UReg . The output register AREG downstream comparator Cf. now continuously compares the content of this output register with the counts present in the supplied hearing line unit ST Zäh leranordnung ZSZ, the terminal means to the other in all line existing corresponding counter arrangements in synchronism. As already mentioned above, the counter readings of the counter arrangement mentioned mark the time slots and the time slots within each first time-division multiplex frame. A memory cell content now remains stored in the output register AReg until there is a match between the values compared with one another, ie until the transmission time calculated for the respective line circuit matches the current time indicated by the counter reading of the counter arrangement. If this correspondence is present, the transmission control circuit SST receives a corresponding control signal from the comparator Vgl . The latter then sends a send request signal to the associated interface circuit LS 1 . On the basis of this signal, this interface circuit takes over the information signals already buffered in the takeover register UReg and sends them to the line connection device following in the ring line system.

For a detailed representation of a transmission process, a time is now assumed at which a transmission request signal has been issued to the associated interface circuit LS 1 . After the transmission request signal has been given, the transmission control circuit SST controls a read cycle in which the memory cell of the first memory ZSP is read out, which contains information regarding the next transmission time. For addressing this memory cell, the data switch ADR 1 is controlled by a signal on the line L 2 so that the chaining parameters (area K ') that are cached in the output register AReg during the previous transmission process serve as address information . As already mentioned above, this chaining parameter specifies the next memory cell to be addressed. The content of the memory cell addressed in this way is now transferred to the output register AReg by a control signal on line L 4 . In parallel, the associated chaining cell containing the information signals to be sent contains the same chaining parameter within the second memory BSP . For this purpose, the transmission control circuit SST controls the data switch ADR 2 by means of a control signal on the line L 6 so that it can be transmitted. In a subsequent read cycle (controlled via line L 3 ), the takeover register UReg takes over the content of the addressed memory cell of the memory BSP . The takeover register UReg is triggered by the transmission control circuit SST . This is followed by the comparison process shown above.

If the compared values match, the transmission control circuit SST receives a control signal from the comparator Vgl and derives from this the transmission request signal intended for the associated interface circuit LS 1 . On the basis of this signal, the latter takes over the information signals to be transmitted which are buffered in the transfer register UReg. A send process is now complete. This is followed by the addressing of the next memory cells of the memories ZSP and BSP in the manner already illustrated. Through constant repetition of these illustrated processes, each memory cell linked for a transmission process is addressed once within each first time-division multiplex frame. This ensures that the information signals to be sent out from the line circuits T 1 to Tm are transmitted within the duration of a time-division multiplex frame to the associated interface circuit LS 1 and are transmitted by the latter to the line connection device following in the ring system.

It should be noted here that the broadcast shown operations to avoid transmission delays ranked before the calculation of the transmission times and before the Have information signals to be sent stored.

In addition, it should be noted that the illustrated before courses for each of the Lei involved in a connection tion circuits run if an information system Signal transmission in both directions see is. In this case the called line gets connection device for the determination of the transmission time point required address information from each Weil called line connection facility at the Verbin with a separate pipeline system Splits.  

Finally, it should be noted that the above Operations corresponding operations expire when the In formation signals according to a time division principle are transferred according to the corresponding one Line circuits of all line connection equipment a time slot that cyclically repeats each other the following first time division frames Time slots for information signal reception available standing and according to that in a second, with the consequence frequency of the time slots repeating periodically Time-division multiplex frames of each line connection device a specific time slot in the respective time slot assigned.

Claims (7)

1. A method for determining the transmission times for the transmission of information signals in the case of an existing connection from a first line connection device ( ST 1 to STn ) to a second line connection device of a telecommunication switching system in which the line circuits supplying and / or discharging the information signals ( T 1 to Tm ) connected line connection devices are interconnected via a clock-controlled, directionally dependent ring line system ( LB ) on which the information signals are transmitted according to a time-division multiplex principle, characterized in that
that all of the ring line system connected Lei tung terminal means a common time compartment (ZFN) of cyclically repeated in successive first time division multiplex frame (ZM) time slots occurring (Zf 1 to ZFN) for the in formation signal receiving is available,
that in a second time-division multiplex frame repeating periodically with the repetition frequency of the time slots, each of the line circuits connected to the line connection devices is assigned a specific time slot ( ZT 1 to ZTm ) in the respective time slot for the information signal recording ,
that is (in Reg 2) and based on a one provided for the information signal recording Lei tung terminal means determining address information (in Reg 1) the transmission time to the acquisition of the Informationssignalauf provided for line connection means determines in the respective line connection means on the basis of these respective address information,
that this transmission time is subtracted from the duration of the first time multiplex frame and
that in accordance with the difference determined in this way, the possible time slot within the respective first time-division multiplex frame based on its frame start and the associated transmission time slot are defined. 2. The method according to claim 1, characterized in that the respective transmission time is determined by first forming the difference between the numbers assigned to line connection devices to be included in an information signal transmission ( Diff 1 ) which number the line connection devices contained in the ring line sequentially , and that this difference is then multiplied by a predetermined amount of time ( MUL ), by which the duration of the signal transmission between two in the ring line system immediately adjacent line connection devices is specified. 3. Circuit arrangement for carrying out the method according to claim 1 or 2, with line connection devices connected via a clock-controlled, directionally dependent ring line system ( LB ) ( ST 1 to STn ), to the information signals supplying or discharging line circuits ( T 1 to Tm ) connected sen, characterized in that each line connection device contains a transmission control circuit ( SST ) which uses an address information determining the respective line connection device (e.g. ST 1 ) and on the basis of a line connection device provided for an information signal recording (e.g. ST 3 ) determining address information determines the transmission time to the line connection device ( ST 3 ) provided for the information signal, subtracts this transmission time from the duration of a first time-division multiplex frame, in accordance with the difference determined in this way within the respective first time ltiplex frame based on the beginning of the frame in question and the associated transmission time slot are determined and details regarding the transmission time slot and associated transmission time slot are recorded during the duration of a connection. 4. Circuit arrangement according to claim 3, characterized in that the transmission control circuit ( SST ) contains a microcomputer. 5. Circuit arrangement according to claim 3 or 4, characterized in that with the transmission control circuit ( SST ) each line connection device ( ST ) a first memory ( ZSP ) is connected, the slots for storing the respective transmission time slots and transmission time indicating control variables in the Line circuits ( T 1 to Tm ) individually associated memory cells serve that the relevant transmission control circuit ( SST ) is assigned a counter arrangement ( ZSZ ) which, together with corresponding counter arrangements of all the other line connection devices associated transmission control circuits, is operated synchronously in such a way that they designated within each first time-division multiplex frame ( ZM ) by their counter positions the time slots and time slots contained in the relevant time-division multiplex frame and that with the output of the relevant transmission control circuit ( SST ) belonging to the counter arrangement ( ZSZ ) and with the output of the associated audi gene first memory ( ZSP ) a comparator ( Vgl ) is connected, the determination of a correspondence between the respective counter position of the counter arrangement ( ZSZ ) and one of the control variables stored in the relevant first memory ( ZSP ) a trigger signal for triggering the transmission of information signals from the respective line circuit in question ( T 1 to Tm ). 6. Circuit arrangement according to claim 5, characterized in that the respective transmission control circuit ( SST ) is followed by a second memory ( BSP ), which corresponds to the number of associated line circuits ( T 1 to Tm ) corresponding number of memory cells for intermediate storage of information signals to be sent and which can be effectively controlled upon delivery of a trigger signal from the associated comparator ( cf. ) for the delivery of temporarily stored information signals. 7. Circuit arrangement according to claim 5 or 6, characterized in that the respective memory control circuit ( SST ) connected to the first memory ( ZSP ) is connected to an output register ( AReg ) which, at the time of sending out information signals , provides information for a next one Transmission timeslot and an associated transmission timeslot from the relevant first memory ( ZSP ) takes over, which are then comparable with the meter reading of the associated meter order ( ZSZ ).