DE2048037C3 - Method and circuits for the synchronization of a telecommunications network operated in a time division - Google Patents

Description

State of the art

As is well known, the receiving devices of each terminal must access the time division multiple connections corresponding transmission devices of the remote station are synchronized. This prepares in simple connections no difficulties with only two terminals, and the methods for doing this are known. On the other hand, it is difficult to synchronize in a network with a central point for larger numbers of channels and several branch offices for smaller numbers of channels. Although the receiving devices of the Remote stations can simply be synchronized with the transmission facility of the central station, however it is Because of the different transit times, it is difficult to switch the receiving device to the different To synchronize the transmission facilities of the branch offices.

Various proposals for ways of synchronizing time division networks have become known. An attempt was made to compensate for the mentioned runtime differences. So used for example one in the Review of the Electrical Communication Laboratory (Japan), Vol. 15, No. 11 12. 1967, pp. 815 to 853, in particular pp. 825 to 829, published proposal by control changeable runtime chains. These methods are very complex, possibly for long-distance traffic reasonable, but too uneconomical for local transport.

task

The invention specified in claims 1 and 4 is therefore the object of a method and a circuit for performing the method specify through which a communication network operated in the line multiple with a central point and several branch offices, preferably networks in the local or district area, in a simple and therefore more economical way Way can be synchronized.

benefits

By using the method it is possible, for example, to divide subscriber groups into several scattered living spaces, each with a branch office via only two double lines through the particularly to connect economical time division multiplex facilities to the general communications network.

Advantageous further developments of the invention are described in claims 2, 3 and 5 to 8. Through These developments according to claims 3, 7 and 8 is achieved that in the event of a malfunction Branch office at least the connections between the branch offices closer to the central office and the Central office remain operational.

Presentation of the invention

The invention is explained below with reference to exemplary embodiments of circuits for implementation of the procedure explained in more detail. This shows

1 shows a simplified overview current flow of a transmission link with a central point and several branch offices.

2 shows an overview current flow of a branching device for carrying out the method.

F i g. 3 and 4 overview current flows of two embodiments of switching devices that can be used in the branching device.

The overview flow of FIG. 1 shows a route plan of a time division multiple message system with, in the example, four stations, namely a central point ZS and three branch points ASi, AS2 and ASn. Each of these four stations is equipped with a Zcitviclfach-Endstclle ES with a transmitting and a receiving device 5 or E. All terminals ES have the same structure and differ only in their equipment for different numbers of channels that can be transmitted by them. The number of channels that can be transmitted from the terminal of the central point ZS is equal to the sum of the channels that can be transmitted by the terminal points of the branch offices AS \ to ASn . Direct connections are only provided between the central point on the one hand and the external points on the other hand, but not between the external points among themselves, as is indicated by the directional arrows. The branch offices, with the exception of the last ASn, with the greatest distance from the central office also contain a branching device AG. The channels of each connection between the central office and each branch office expediently and advantageously immediately follow one another in time within the impulse frame and each form a group within the frame, so that the (15 impulse frame contains as many communication groups as there are external stations in the network.

Fig. 2 shows the overview current flow of a branching device between the central point ZS and any number of further branch offices ASx. Of course, further external points with branching channels can also be provided between the central point and the branching device shown. As also shown in FIG. 1, a terminal ES with a transmitting device S and a receiving device £ is connected to the branching device.

For the transmission direction from the central station ZS for consideration and further branches ASx the branch device contains a known regenerative amplifier Fl, in addition to the restored through it in its original form coming from the central office signals Sl usually also from this one Schriltaktfolge Tl wins and can deliver. The step cycle Tl obtained controls the receiving device E of the terminal ES directly connected to the branching device. The signals Sl at the output of the amplifier Vl contain the complete pulse sequence emitted by the central point; after the amplifier F1, they are sent both to the line to further branch offices and to the receiving device E of the terminal ES of the branch office under consideration. The decoupling that is common at the fork of the lines is not shown for the sake of simplicity. The terminal ES evaluates in a known manner from the signal sequence supplied to it only the parts intended for it, since it is only equipped with some of the possible channel units.

For the transmission direction from the distant further from the central office branches ASx to the central authority CA the branching device comprises a second Rcgcncrativverstärker V2, which restores the original form of coming from remote locations signals Sl and from these a Schritltaktfolge T 2 is derived. The signals 52 are fed firstly to a first input E1, to a switching device U, which will be described in detail later, and secondly to a system known per se for recognizing the frame and possibly also the over-frame synchronization signals. In case of operating with pulse code modulation (PCM) Zcitviclfachsystems this circuit usually consists of a shift register SR and connected thereto, the logic circuit L. The incoming in the shift register SR and weitergcschobcncn by the clocks Tl therein signals Sl be on by the logic circuit L the occurrence of the frame or Ubcrrahnicnsynchronisicrzeichcn is monitored, the logic circuit emitting corresponding output signals R and O at the time of the occurrence of these Synchronisierzichcn. The clock sequence T 2 obtained in the branching device, the synchronizing signals R and possibly 0 are fed firstly to the switching device S of the terminal ES and secondly to the switching device V. They ensure in the Scnclecinrichtung S of the terminal ES that the output signals Si supplied by it are emitted at prescribed times, and stcuLMii the switching device V in such a way that either its first input E1 or its second input E2, to which the output signals V 3 are fed to the transmitter S of the terminal HS , is connected to output A ilucm. This means that in the direction of the central station ZS at output A of the switching device (/ at different times either those from the remote

Signals S 2 coming from the branch offices or the signals S3 coming from the terminal directly connected to the branching device. A further amplifier V 3 can be inserted into the line to the central point ZS.

For the changeover device U in the branching device are shown in FIGS. 3 and 4 two different exemplary embodiments given.

The circuit according to FIG. 3 can be used in cases in which either no additional identification, z. B. dialing characters in addition to voice signals are to be transmitted or in which the additional characteristics next to the (e.g. voice) signals are transmitted in the same time channel.

The switching device according to FIG. 3 consists of two AND circuits U1 and U 2, each with two inputs, the outputs of which lead via an OR circuit O with two inputs to output A of the switching device. The first input of the AND circuit Ul is connected to the input El of the switching device and the first input of the AND circuit U 2 is connected to the input E2 of the switching device. The second inputs of the AND circuits Ul and Ul are each connected to one of the outputs of a bistable multivibrator KSl. Depending on the switch position of the bistable multivibrator KSl , one of the AND circuits Ul or i / 2 is switched on at any time, the other is blocked and one of the inputs E1 or E 2 of the switching device is transmitted through to output A. The bistable flip-flop KS1 is set at the beginning of a pulse frame by the frame synchronization signal R in an initial position. The frame synchronization character R also sets a counting chain Z1 in an initial position. The the Rahtncnsynciironisicrzcichen R step acts 7 "2 switch continues the counting chain, and the counting chain Control logic circuit Ll delivers to a predetermined number of Schrittaklen a bistable multivibrator KSL in its second switching state umslcucrndcs output signal. The switching of the flip-flop KSL and thus the switching device takes place at the end of the pulse sequence emitted either from one of the remote locations further away from the central location or from the remote location under consideration. The cannula to be transmitted from the individual remote locations are expediently arranged in channel groups within the pulse frame in such a way that their sequence corresponds to the sequence of the outer locations along the transmission path The transmission device then only has to ring once within a pulse frame If the UnischaltceinrichUing must therefore rewrite several times during the duration of a pulse frame, further logic circuits must monitor the counting chain Z 1 for other counting positions and the flip-flop KS1 must be switched to the other switching state for each output signal of one of the logic circuits.

In the event that a common identifier channel for all channels is provided for the transmission of additional identifiers, the assignment of this identifier line channel to one or more channels changing from lir.piilsiahtneri to pulse frames and this assignment being carried out by multiple frame identifiers transmitted in the identifier time channel, the in Fig 4 can be used. The circuit corresponds in part to the assemblies AND circuits l / l and U 2, OR circuit O, flip-flop KSl, counting chain Zl and logic circuit Ll of the circuit according to FIG. 3, but the AND circuits Ul and 1 / 2 three inputs each and the OR circuit O four inputs. The description given for the circuit according to FIG. 3 also applies to the mode of operation of this part of the circuit. In addition, the circuit according to FIG. 4 two further AND circuits i / 3 and L'4 each with three inputs, the outputs of which are connected to the third and fourth input of the OR circuit. The first input of the third AND circuit 1/3 is connected to the input El and the first input of the fourth AND circuit t / 4 is connected to the input E2 of the switching device. The circuit also contains a second and a third bistable multivibrator KS2 and KSi, at least one further counting chain Z2 and at least three further logic circuits L 2, L3 and L 4. The first output of the second multivibrator KS2 is connected to the third inputs of the first and second second AND circuit U 1 and (72, the second output of the second flip-flop KS2 with the third inputs of the third and fourth AND circuits 1/3 and U 4. The second flip-flop KS2 supplies in its first switching state at the beginning of a pulse frame on its first output a signal to the first and second AND circuits l / l and U 2, which allows the switching of these AND circuits as well as in the circuit of FIG. 3, while the inverted signal at its second output the third and fourth AND Circuit U 3 and U 4 blocks device L 2, the second flip-flop KSl is reversed into its second switching state, in which it blocks the first and second AND circuits Ul and U 2 and allows the third or fourth AND circuit U 3 or U 4 to be switched through. After the end of the Kennzcichenzcitkanals, determined either, as shown, by a further, the counting position dsr first counting chain Zl monitoring logic circuit L3, or by a third, not shown, starting with the occurrence of the output signal of the logic circuit L 2, the step files c The second toggle switch KS 2 is reset to its first (initial) position again. The first output of the third trigger circuit KS 3 is connected to the second input of the third AND circuit U3 and the second output of the third trigger circuit KSi is connected to the second input of the fourth AND circuit U4. As a result of the superframe synchronization signal V supplied, both the third bistable multivibrator KSi and the second counting chain Z2 are set to an initial setting. The following frame synchronization signals R switch the counting chain Z 2 further, and the logic circuit L 4 monitoring the counting chain delivers an output signal which reverses the flip-flop KSi in its second switching state at the beginning and during the duration of a certain pulse frame within the tibcrrahniens. The downshift

709 544/136

the flip-flop KS3 in its first switching state can be done either by the next superframe synchronization character Ü or by the output signal of a further, not shown, a certain count position of the counting chain Z 2 monitoring logic circuit.

The circuit according to FIG. 4 allows the identification of any channel to be always classified in the designated position of the identification time channel within a pulse frame and in the pulse frame provided for this purpose within a superframe, regardless of whether the useful channels adjacent to the identification time channel belong to the same or a different channel group than the channel, whose identification is to be transferred. For example, via input E 1 of the switching device, the pulse train coming from remote locations at a greater distance from the central office, with the exception of the identification time channel, runs via the AND circuit Ul, and the pulse train coming from the terminal directly connected to the branching device, with the exception of the identification time channel, uses the AND -Circuit Ul alternately to output A. During the position and duration of the identification time channel determined essentially by the counting chain 21 and the logic circuit L1, the AND circuits I / I and U 2 are blocked and the AND circuits [/ 3 and 174 released. During this period, depending on certain pulse frames within the superframe and regardless of whether the input El or the input El was connected to the output A immediately before, either the input El via the AND circuit t / 3 or the input E2 via the AND circuit U 4 connected to output A. For example, in certain pulse frames at output A, the identifiers coming via input E2 are stored in a pulse train coming via input El.

The step rate for the two transmission devices is determined by the terminals at the ends of the transmission path, ie by the central office and the branch office furthest away from it. The same places also supply the synchronization characters for the pulse frames and, if applicable, for the superframes. One of the two terminal points, preferably the central point, can serve as a terminal and the second terminal point can use the tackle received from it again to transmit in the opposite direction. However, if one of the branch offices with a branching device with the structure described so far is missing clock and synchronization / calibration of branch offices further away from the central branch, be it because the branch itself has failed or the line to it has been interrupted, operation between those closer to the central branch would be located branch offices and the central office are no longer possible. In order to maintain the operation between a part of the branch office closer to the central office and the central office in the event of failure of a part further away from the central office, each branch office with a branching device must be able to generate or generate clock and synchronization characters for the transmitter itself. For this purpose, a synchronizable clock generator can be connected downstream in the branching device of the device Vl, in Fig. 2, to obtain the step rate from the pulse train arriving from the central office further away; . The output signals of the clock generator switch the known device SR and L in FIG. 2 for obtaining the frame and superframe synchronization characters, which is also assigned a monitoring, counting and switching device which, after determining the absence of the frame and possibly also the superframe synchronization characters over a specified period of time, either the device for obtaining the frame and superframe synchronization characters in Branch device switches over in such a way that it generates the missing characters itself, or switches on the synchronization character generator present in the terminal device of the branch office. For another possibility of continuing the operation of a branch office if it is not supplied with a pulse train from further branch offices, the clocks T1 received from the central office by the receiving device of the terminal of the branch office are used to control the transmitting device of the same terminal. For this purpose, the device V 2 in FIG. 2 for obtaining the step is dictated by the coming of more distant offices pulse sequence followed by a controlled, time-delayed switch by the obtained step angle (72 in Fig. 2) in the absence of step act Tl extracted from the coming from the central office pulse train clocks Tl to the transmitting means 5 for clocking the pulse train emanating from this and the synchronizing character generator in the transmitting device. Furthermore, in every case of the operation of such a shortened route, the control of the switching device is ensured by the step cycle and by the frame and superframe synchronization characters of the terminal 5 of the terminal in the last operational branch and instead of the pulse train coming from previous branch in normal operation the first Input E1 of the switching device is supplied with a sequence of pulses with changing values, synchronized by the step clock, in order to supply the receiving part of the central station with the complete pulse frame necessary for synchronization.

For this 2 BhUt drawings

Claims (8)

A / ι claims: 1. Seduce to synchronize a telecommunications network operated in a time division with a central point for a larger choice of channels and at least two along a connecting path arranged and connected in parallel to these branch offices for smaller numbers of channels, their total number (sum of the useful channels of all branch offices) is equal to the number of useful channels the central office, with direct communication links only between the central office and the branch offices, but not between the branch offices among themselves, furthermore with One transmitting and one receiving device each in the central office and in the branch offices, whose Receiving devices are synchronized by the transmitting device of the central office, thereby characterized in that by of the sending device of the branch most distant from the central office Clock pulses and synchronization characters on their way to the central office one after the other via the other branch offices and the transmission facilities of these branch offices and the Synchronize receiving device of the central office, and that the from each branch in Direction to the central office outgoing useful signals in the sequence of in the same direction of The useful signals supplied to the preceding branch offices are inserted in the correct position. 2. The method according to claim 1, characterized in that that the transmitting device of the branch most distant from the central office via the receiving device of the same branch from the transmitting device of the central office is synchronized. 3. The method according to claim 1, characterized in that of the branch offices, all are set up to generate and send out synchronization characters if there are no synchronization characters the branch office automatically abandons the branch office with the greatest distance from the central office as the generator of the step files and synchronization characters for the The direction of transmission to the central office takes over, in which the synchronization character is used for the first time fails to appear. 4. Sound system for performing the method according to claim 1, in which each of the branch offices with the exception of the branch most distant from the central office on the trunk line side is preceded by a branching device, characterized in that the branching device {AG) for the direction of transmission from the central office to further branch offices the means known per se for the decoupled connection of the time-multiplexing terminal of the branch point and for the transmission direction from further distant branch offices to the central office firstly the device (Vl) known per se for acquiring the step file (T2) and the devices (SR, L) to obtain the frame and superframe synchronization characters (R, U) from the signals coming from more distant external locations and, secondly, an electronic switching device (U) that contains the clocks and synchronization characters obtained, firstly, the transmission part (S) of the directly connected time division End device (ES) synchronizing eren and secondly control the electronic Umschalteeinrichtunu (U) that a first input (1: 1) of the'Umschalteeinrichtung (U) the signals coming from more distant branch offices (.S "2) and a second input (El) of the switching device (U ) The signals (.V3) coming from the directly connected terminal are supplied, and that the switching device (U) each receives a certain of the signal sequences supplied to it according to a preset selected by the number and position of the channels supplied to the inputs of the switching device and depending on the Appearance of the frame and, if applicable, overriding synchronization characters and the number of subsequent step files are switched through to the output (A) of the switching device and further in the direction of the central station (Fig. 1 and 2). 5. A circuit according to claim 4, characterized in that the switching device consists of two AND circuits (Ul, Ul) each with two inputs, an OR circuit (O) of a counting chain (Zl), at least one logic monitoring the switch position of the counting chain Circuit (Ll) and a bistable multivibrator (KSl) that the first input of each of the two AND circuits (Ul, Ul) is connected to one of the two inputs (£ 1. El) of the switching device that the outputs of the AND Schaltuneen (i / 1, Ul) are each connected to an input of the OR circuit (O), the output of which is also the output (A) of the switching device, that the frame synchronization character (R) the counting chain (Zl) and the bistable multivibrator ( KSl) sets in a starting position and the counting chain (Zl) is switched on by the step files (Tl) so that the logic circuit (Ll) a bistable toggle switch upon reaching certain circuits of the counting chain (Zl) given by the presetting Altung (KSl) emits switching signal and that the two outputs of the bistable trigger circuit (KS 1) are each connected to one of the second inputs of the two AND circuits (C1, £ / 2 in Fig. 3). 6. A circuit according to claim 4 for time multiplexing systems in which a selected time channel is provided for the transmission of the identifier of several useful channels, with other useful channels being assigned from pulse frame to pulse frame of this identifier time channel, characterized in that the switching device consists of four AND circuits (U1 to U 4) with three inputs each, an OR circuit (O) with four inputs, at least two counting cells (Zl, Z2), at least two logic circuits (Lt, L 2) monitoring the first counting chain (Zl), at least one the second Counting chain (Z 2) monitoring logic circuit (L 4) and three bistable multivibrators (KSl to KS3) that the first input (El) of the switching device is connected to the first inputs of the first and third AND circuit (L / 1, t / 3) that the second input (£ 2) of the switching device is connected to the first Inputs of the second and fourth AND circuit (Ul, t / 4) that the outputs of the AND circuits (LM to i / 4) are connected to one input each of the ODIiR-SLi, aliting (O) and the output of the ODLR- circuit at the same time the training ζ gear (/ 1) of the Umsehaheeinrichlung is that the first counting chain (Zl) and the first flip-flop (KSL) by the frame sync / .eichen (R) into a starting position are settable in that the first counting chain (Zl ) through the step clocks (T 2) _{lu it} is possible to switch further that the logic circuit (Ll) monitoring the first counting chain (Zl) when reaching certain, given by presetting, the end of a group of cannulas within a pulse frame characterizing switching stage of the first counting chain (Zl ) the first flip-flop (KSl) Umscnaltendes signal emits that the two outputs of the first flip-flop (KSl) are connected to one of the second inputs of the first and second AND ?. <> circuit (LM, L / 2) that the second toggle switch (KS2) through the output signal of a further, the first counting chain (Zl) monitoring logic circuit (L2) upon reaching a switching position characterizing the beginning of the identification time channel in its second switch position and reversible after the end of the identification time channel by the output signal of another either the first counting chain (Zl) or a further, clocked counting chain monitoring logic circuit (L 3), started by the output signal of the logic circuit (L2) determining the beginning of the identification channel, can be switched back to its first switching position. that the first output of the second flip-flop (KS2) is connected to the third inputs of the first and second AND circuit (L / 1, U2) and the second output of the second flip-flop (KS2) is connected to the third inputs of the third and fourth AND circuit (U 3, U 4), that the second counting chain (Z2) and the third flip-flop (KS3) can be set in an initial position by the superframe synchronization character (Ü), that the second counting chain (Z 2) by the frame synchronization character (R ) it can be switched further that the logic circuit (L 4) monitoring the second counting chain (Z 2) upon reaching certain switching positions of the second counting chain (Z2) which are given by presetting and which characterize certain frames within the superframe, a signal that switches the third toggle switch in its second switching state outputs that the third flip-flop (KS 3) in its first switching state either by the next superframe synchronization character ((J) or by the output gsignal of a further logic circuit that monitors a specific counting position of the second counting chain (Z2) can be switched back, and that the two outputs of the third flip-flop (KS3) are each connected to one of the second inputs of the third and fourth AND circuit (t / 3, 1/4). 7. A circuit according to claim 4 for carrying out the method according to claim 3, characterized in that the device for obtaining the step rate from the pulse train arriving from remote units at a greater distance from the central unit has a synchronizable clock generator which is obtained in normal operation by the Step clock is synchronized and oscillates freely in the absence of step clocks, so that the output signals supplied in each case by the clock generator are used to advance the shift register (SR) of the known device for obtaining the frame and superframe synehionization characters, that this device is assigned a monitoring, counting and switching device is, with the task of determining the absence of the frame, possibly also the superframe synchronization over a predetermined one. Period of time to switch either the device for obtaining the frame and top synchronization / calibration in the branching device in such a way that it generates the missing characters itself, or the device in the end positioner! to switch on the existing syncronization waveform generator of the remote station. 8. A circuit according to claim 4 for performing the method according to claim 3, characterized in that the device for obtaining the step act from the incoming IiTij one or more normally closed contacts is connected downstream, with the task, in the absence of signals from further external locations and thus of the step cycle, to transmit the step (T1) obtained from the signals coming from the central station to the transmitting device (S) for clocking and synchronizing the impulse sequence emanating from it ( Fig. 2).