DE2048037A1 - Method and circuits for the synchronization of a telecommunications network operated in a time division - Google Patents

Description

Methods and circuits for the synchronization of one in the time multiple operated communications network as is well known in time division multiple connections Receiving facilities of each terminal on the corresponding transmitting facilities of the Can be synchronized with the remote station. This prepares in simple connections with just two terminals no difficulties, and the procedures for doing this are known. Difficult on the other hand, the synchronization in a network with a central point is for larger ones Number of channels and several branch offices for smaller numbers of channels. You can the receiving facilities of the branch offices simply on the transmitting facility of the Central point are synchronized1 but it is because of the different runtimes difficult to switch the receiving device to the various transmitting devices to synchronize the branch offices.

There are several suggestions for ways to synchronize has become known from time division networks.

An attempt was made to compensate for the mentioned runtime differences. For example, one used in the Review of the Electrical Communication Laboratory (Japan), Vol. 15, Numbers 11-12, 1967, pp. 815 ... 85, in particular pp. 825 ... 829, published a proposal through control of changeable runtime chains, this procedure are very expensive, but may be justifiable for long-distance traffic local transport too uneconomical. In contrast, the method according to the invention is preferably suitable for networks in the local or district area.

The inventive method for synchronizing a time multiple operated communications network with a central point for a larger number of channels and at least two branch offices for smaller ones arranged in the course of the connection Channel numbers, whereby the sum of the useful channels of the external locations is equal to the number the Nutzkanälo of the central office, with direct communication links only between the central office and the issuing offices, but not between the branch offices are provided with each other, both the central office and the branch offices Each contain a transmitting and a receiving device, and wherein the receiving devices of all branch offices through the transmission facility of the central office synchronized is characterized by the fact that from the transmitting device of the branch office Clock pulses and synchronization signals sent with the greatest distance from the central station on their way to the central office one after the other through the remaining branch offices are performed and through these clock pulses and synchronization signals the transmitting devices these branch offices and the receiving device of the central office are synchronized and that the outgoing from each branch in the direction of the central office Useful signals in the sequence of in the same direction from the previous external locations supplied useful signals are inserted in the correct position.

The invention is illustrated below by way of working examples of circuits for performing the method explained in more detail. To this end, Fig. 1 shows a simplified cautious 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 implementation of the method, FIGS. 3 and 4 overview streams of two embodiments of Umschaltein directions that can be used in the branching device.

The overview flow of FIG. 1 shows a route plan of a Time division multiple communication network with four stations in the example, namely a central point ZS and three branch offices AS1, AS2 and ASn. Each of these four stations is equipped with a time division multiple terminal ES with one transmitting and one receiving device each S or E. All end stations ES have the same structure and only differ in terms of their number 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 office ZS is the same the sum of the endpoints of the branch offices AS1 ...

ASn transmittable channels. Immediate connections are only between the central office on the one hand and the branch offices on the other hand, but not between the branch offices provided one below the other, as indicated by the directional arrows is. 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 each Connection between the central office and each branch office follow within the The pulse frame is expediently and advantageously timed directly on top of one another and form one group each within the frame, so that the impulse can generate as many channel groups contains how there are branch offices in the network.

Fig. 2 shows the overview current flow of a branching device between the Zentralstellc ZS and any number further branch offices ASx. Of course, you can also choose between the central office and the one shown Junction device further branch offices with branch devices can be provided.

Is connected to the branching device, as also shown in Fig. 1, a terminal ES with a transmitting device S and a receiving device E.

For the direction of transmission from the central point ZS to the considered and for further branch offices ASx, the branching device contains a known regeneration unit strengthener Vi, the next to those restored by him in their original form Signals S1 coming from the central point usually also consist of a sequence of steps T1 wins and can give up. The obtained step clock sequence T1 controls the receiving device E of the terminal ES directly connected to the branching device. The signals St at the output of the amplifier V1 contain the complete, from the central point transmitted pulse train; they are after the amplifier V1 both on the line to further branch offices as well as to the receiving device E of the terminal ES of the considered branch office given. The usual decoupler at the fork in the lines is not shown for the sake of simplicity. The terminal ES evaluates in the known ISIS from the signal sequence supplied to it, only the parts intended for it are selected, since they is only equipped with some of the possible duct facilities.

For the direction of transmission from the farther from the Zentralstclle remote branch offices ASx to the central office ZS, the branching device contains a second Rogenerati werstarker V2, which the original form of the removed Signals S2 coming from the external locations are restored and a sequence of steps is taken from them T2 derives. The signals S2 are first to a first input EI, a later switching device U described in detail and, secondly, one known per se Circuit for recognizing the frame and possibly also the superframe synchronization characters fed. In the case of a time division system working with pulse code modulation (PCM) this circuit usually consists of a shift register SR and one with this connected logic circuit L.

The incoming into the shift register SR and through the clocks T2 Signals S2 shifted on therein are transferred to the logic circuit L by the Appearance of the frame or. Monitored superframe sync characters, with the logical Circuit at the time of occurrence of these synchronization characters corresponding Output signals R resp.

Ü delivers. The clock sequence T2 and synchronization signals obtained in the branching device R and possibly Ü are first of the transmitting device S of the terminal ES and secondly, the switching device U is supplied. Sio put in the broadcast facility S of the terminal ES ensures that the output signals S3 supplied by it are to be prescribed Times are given, and control the switching device U so, that in given periods of time either their first input E1 or their second input E2, to which the output signals S3 of the transmitting device S of the terminal Es are fed is connected to its output A. So lie in the direction of the central office ZS at the output A of the switching device U at different times either the Signals S2 coming from remote branch offices or from the one with the branching device directly connected terminal station coming signals S3. In the line to the central office A further amplifier V3 can be inserted into ZS.

For the switching device U in the branching device, FIGS. 3 and Fig. 4 two. different execution examples given.

The circuit of Fig. 3 is useful in those cases where either no additional marks. e.g.

Option signs next to speech signals, are to be transmitted or in which the additional identifiers next to the (e.g. voice) signals in the same time channel be transmitted.

The switching device according to FIG. 3 consists of two AND circuits Ul and U2 each with two inputs, the outputs of which via an OR circuit O with two Entrances lead to output A of the switching device. The first The input of the AND circuit U1 is connected to the input EI of the switching device and the first input of the AND circuit U2 with the input E2 of the switching device.

The second inputs of the AND circuits U1 and U2 are connected each with one of the outputs of a bistable multivibrator KS1. Depending on the switch position of the bistable Eipp circuit KSI is therefore one of the AND circuits at any point in time U1 or U2 controlled, the other blocked and one of the inputs E1 or E2 of the switching device is switched through to output A dome. The bistable Flip-flop KS1 is activated by the frame synchronization character at the beginning of a pulse frame R set in an initial position. The frame synchronization character R sets at the same time a counting chain i in an initial position.

The step files T2 following the frame synchronization character R switch the counting chain continues and a logic circuit Lt monitoring the counting chain supplies after a predetermined number of step files the bistable flip-flop circuit tS1 output signal reversing its second switching state. Switching the X toggle switch KSI and thus the switching device takes place at the end of the either from one of the farther away from the central office or from the one being viewed Pulse sequence sent out from the remote office. Those from the individual branch offices are appropriate channels to be transmitted Channel groups within the impulse frame arranged so that their order of the order of the external locations along the Transmission path corresponds. It must then be the switching device within of an impulse frame can only be switched once. Corresponds to the order of the channel groups within the impulse frame not the natural order of the channel groups supplying branch offices and therefore has to use the switching device for the duration of a pulse frame toggle several times, so must further logic circuits monitor the counting chain Z1 for other counting positions and the toggle switch ES1 for each output signal one of the logic circuits in the other Switching state can be switched.

In the event that the transmission of additional indicators is a for all channels common identification time channel is provided, with the assignment this identification time channel to one or more channels of pulse frames Pulse frame changes and this assignment is transmitted in the identification time channel Multiple frame identification takes place, the switching device shown in FIG. 4 can be used. The circuit corresponds in part to the assemblies AND circuits U1 and U2, OR circuit 0, flip-flop KS1, counting chain Z1 and logic circuit L of the circuit of FIG. 3, but the AND circuits Ul and U2 each have three Inputs and the OR circuit 0 four inputs. For how this part works the circuit the same applies to that given for the circuit according to FIG. 3 Description. In addition, the circuit of FIG. 4 contains two further AND circuits U3 and U4 with three inputs each, the outputs with the third and fourth input the OR circuit are connected. The first input of the third AND circuit U3 is with the input E1 and the first input of the fourth AND circuit U4 with the Input E2 of the switching device connected. The circuit also includes a second and third bistable Kippscbaltung KS2 and KS3, at least one more Counting chain Z2 and at least three further logic circuits L2, L3 and L4. Of the The first output of the second flip-flop KS2 is connected to the third inputs the first and second AND circuit Ul and U2, the second output of the second flip-flop KS2 with the third inputs of the third and fourth AND circuits U3 and U4.

The second flip-flop KS2 delivers in its first switching state at the beginning of a pulse frame at its first output a signal to the first and second AND circuit Ul and U2, the switching through of these AND circuits as well allowed as in the circuit of FIG. 3, while the inverted signal on their second output blocks the third and fourth AND circuits U3 and U4. With the beginning of the identifier time channel, determined by a corresponding counting position the first counting point Z1 monitoring logic circuit L2 becomes the second flip-flop KS2 in its second switching state in which it controls the first and second AND circuit U1 and U2 blocks and the switching through of the third or fourth AND circuit U3 or U4 allowed. After the end of the identification time channel, either determined as shown, by a further one that monitors the counting position of the first counting chain Z1 logic circuit L3, or by a third, not shown, with the occurrence of the output signal of the logic circuit L2 starting, the step file of a Time channel counting number chain is the second flip-flop KS2 back in their first (starting) position reset. The first output of the third flip-flop KS3 is connected to the second input of the third AND circuit U3 and the second Output of the third flip-flop KS3 to the second input of the fourth AND circuit U4. Due to the supplied superframe synchronization symbol Ü, both the third bistable flip-flop XS3 and the second counting chain Z2 in an initial position set. The following frame synchronization characters R switch the counting chain Z2 further, and the logic circuit L4 monitoring the counting chain supplies at the beginning and during the duration of a certain pulse frame within the superframe on the flip-flop KS3 reversing output signal in its second switching state. The downshift the flip-flop ES3 in its first switching state can either through the next Superframe synchronization symbol Ü or by the output signal of another 1 not shown, a certain counting position of the counting chain Z2 monitoring logical Circuit take place.

The circuit of Fig. 4 allows the characteristics of any Channel always in the designated place of the identification time channel within a pulse frame and in the pulse frame provided for this purpose within a superframe to be classified, regardless of whether the user channels adjacent to the identification time channel belong to the same or a different channel group than the channel whose identifier are to be transferred. They run, for example, via the input EI of the switching device the impulse sequence coming from remote locations at a greater distance from the central office with the exception of the identification time channel via the AND circuit Ul and that of the with the terminal station directly connected to the branching device Exception of the identification time channel via the AND circuit U2 alternating to the output A. During the essentially through the number chain Zi and the logic circuit L2 determined position and duration of the identification time channel are the AND circuits U1 and U2 blocked and the AND circuits U3 and U4 released. During this Period is dependent on certain pulse frames within the superframe and regardless of whether the input El or the input E2 with the Output A was connected, either the input EI via the AND circuit U3 or the input E2 is connected to the output A via the AND circuit U4. So ground it for example, in certain pulse frames at output A, those coming via input E2 License plate in an over the input EI incoming pulse train stored.

The step act for the two directions of transmission is determined by the End point at the ends of the transmission path, i.e. through the central office and The same locations determined by the remote location furthest away Liefer9 also the synchronization characters for the pulse frames and, if applicable, for the uberframe. One of the two end points, preferably the central point, serve as the control center and the second terminal the clocks received from this use again to send in the opposite direction.

However, it is missing in one of the branch offices with a branching device with the Structure described so far, clock and synchronization signals from further away from the central station remote branch offices, be it because the branch office itself has failed or the line there is interrupted, so there would be an operation between the closer to the central office located branch offices and the central office are no longer possible. To the operation between a part of the branch office that is closer to the central office and the central office to keep up in the failure of a more remote part of the central office, everyone must Remote station with branching device to be able to set clock and synchronization characters to win or generate for the broadcast part. This can be done, for example, in the junction device the device V2, in Fig. 2, for obtaining the step file from the central office more remote branch offices Pulse train a synchronizable . Be connected downstream clock generator, which is obtained in normal operation by the Step file is synchronized and swings freely in the absence of synchronization clocks. The output signals of the clock generator switch the known. Facility SR and L in Fig. 2 for obtaining the frames and superframe sync characters, the additional a monitoring, counting and switching device is assigned, which after the detection the lack of the frame and possibly also the superframe synchronization characters a predetermined period of time either the device for obtaining the frame and Switches superframe synchronization characters in the junction device in such a way that these the missing characters are generated by themselves, or those present in the terminal device of the branch office The synchronization character generator switches on. For another way to continue of the operation of a branch office if this does not have a pulse train from further branch offices is supplied, they are sent by the receiving device to the terminal of the branch office clocks T1 received by the central office for controlling the transmission device of the same Terminal used. For this purpose, the device V2 in FIG. 2 is used to acquire the step act from the impulse sequence coming from more distant branch offices one gained by the Step cycle (T2, Fig. 2) controlled, time-delayed changeover switch connected downstream, the one coming from the central office in the absence of the step act T2 Pulse train obtained clocks T1 to the transmitting device S for clocking the pulse sequence emanating from this and turns on the synchronization character generator in the transmitting device.

Furthermore, in each case the operation is shortened Route the control of the switching device through the step act and through the Frame and superframe synchronization characters of the transmitting part S of the terminal in the last operational branch ensured and instead of the normal Operation of previous external locations, impulse sequence coming to the first input EI of the switching device is a sequence of synchronized by the step clock impulses that change in their values are fed to the receiving part of the central office to deliver the complete impulse frame necessary for synchronization.

Claims (7)

P a t e n t a n 5 p r ü c h e i) Method for synchronizing a time-multiply operated Communication network with a central office for a larger number of channels and at least two branch offices arranged in the course of the connection for smaller numbers of channels, where the sum of the useful channels of the 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 blind, with both the central office and the branch offices each having a and a receiving device, and wherein the receiving devices include all External locations are synchronized by the transmission device of the central office, characterized in that by the transmitting device of the branch office with the greatest distance from the central office and clock pulses sent out synchronously zodiac signs on their way to the central office one after the other through the remaining branch offices are performed and through these clock pulses and synchronization signals the transmitting devices these branch offices and the receiving device of the central office are synchronized and that the outgoing from each Auesenstelle in the direction of the central office Useful signals in the sequence of in the same direction from the previous external location supplied useful signals are inserted in the correct position. 2) Method according to claim i, characterized in that the transmitting device the branch office with the greatest distance from the central office via the receiving device the same branch office synchronized by the transmission device of the central office will. 3) The method according to claim 1, characterized in that Jedo the Branch offices are set up to generate and send out synchronization characters and if there are no synchronization characters from a remote location at a greater distance from the central office automatically the task of the branch office with the largest Removal from the central office as the generator of the step files and synchronization characters for the direction of transmission to the central office. 4) circuit for performing the method according to claim i, wherein Each of the branch offices with the exception of the branch office with the greatest distance A branching device is connected upstream from the central office on the transmission side, characterized in that the branching device (AG) for the transmission direction from the central office to further branch offices the means known per se for decoupled connection of the time division device of the branch point and for the Direction of transmission from remote branch offices to the central office firstly known per se Facility (V2) to win the step act T2 and the means (SR, L) for obtaining the frame and superframe synchronization symbols (R, Ü) from the signals coming from more distant external locations and, secondly, one electronic switching device (U) that contains the clocks and synchronization characters obtained firstly the transmitting part (5) of the directly connected time division multiplexer terminal (ES) elynchrotlize and secondly the electronic switching device (U) control that a first input (E1) of the switching device (U) from the remote ports External stations coming signals (S2) and a second input (E2) of the switching device (U) the signals (53) coming from the directly connected terminal are supplied be, and that the switching device (U) in each case a certain of the supplied to it Signal sequences according to one of the number and location of the inputs the switching device supplied channels selected preset and dependent the occurrence of the frame and, if applicable, superframe synchronization and the number of subsequent step files on the output (A) of the switching device and further switches through in the direction of the central office (Fig. 1, Fig. 2). 5) Circuit according to claim 4, characterized in that the switching device consists of two AND circuits (U1, U2) with two inputs each, one OR circuit (0) one Counting chain (Z1), at least one of the switching positions of the Counting chain monitoring logic circuit (L1) and a bistable trigger circuit (KSI) that the first input is connected to each of the two AND circuits (Ut, U2) is connected to one of the two inputs (E1, E2) of the switching device that the outputs of the AND circuits (U1, U2) are connected to one input each OR circuit (O), where the output of the OR circuit is also the output (A) the switching device is that the frame synchronization character (R) is the counting chain (Z1) and the bistable flip-flop (Ksl) sets in an initial position and the Counting chain (ZI) is switched through the step file (T2) that the logical Circuit (L1) when reaching certain circuits given by the pre-setting the counting chain (Z1) emits a signal that switches the bistable multivibrator (KS1) and that the two outputs of the bistable flip-flop device (KS1) are connected to each one of the second inputs of the two AND circuits (U1, U2), (Fig. 3). 6) circuit for performing the method according to claim 4 for time division multiple systems in which a selected time channel for the transmission of several identifiers Useful channels is provided, this identification time channel from pulse frame to pulse frame is assigned to other useful channels, characterized in that the switching device consists of four AND circuits (U1... U4) with three inputs each, an OR circuit (O) with vior inputs, at least two counting chains (Z1, Z2), at least two logic circuits that monitor the first counting chain (Z1) (L1, L2), at least one logic circuit that monitors the second counting chain (Z2) (L4) and three bistable multivibrators (KS1... KS3) that the first input (Ei) of the switching device is connected to the first inputs of the first and third AND circuit (Ui, U3) that the second input (E2) of the switching device is connected to the first inputs of the second and viorten AND circuit (U2, U4) that the outputs of the AND circuits (U1... U4) are each connected to one Input of the OR circuit (0) and the output of the OR circuit at the same time the output (A) of the switching device is that the first counting chain (zi) and the first toggle circuit (KS1) can be set in an initial position by the frame synchronization character (R) are that the first counting chain (Z1) can be advanced through the step file (T2), that the logic circuit (L1) monitoring the first counting chain (Z1) when it is reached specific, preset, the end of a group of channels within of a pulse frame characterizing switch positions of the first counting chain (Z1) the first toggle switch (KS1) emits a switching signal that the two outputs the first flip-flop (KS1) are each connected to one of the second inputs the first and second AND circuit (U1, U2) that the second Toggle switch (KS2) by the output signal of another, the first counting chain (Z1) switching logic circuit (L2) when reaching the beginning of the Identification time channel characterizing switch position in its second switch position reversible and after the end of the identification time channel by the output signal another, either the first counting chain (Z1) or another, through the output signal the logic circuit (L2) determining the beginning of the identification channel started, clocked counting chain monitoring logic circuit (L3) in its harvest switch position It is possible to switch back that the first output of the second trigger circuit (KS2) is connected is connected to the third inputs of the first and second AND circuits (U1, U2) and the second output of the second flip-flop (KS2) is connected to the third Inputs of the third and fourth AND circuits (U3, U4), which are the second counting chain (Z2) and the third flip-flop (KS3) by the Uberframeynchronisierzeichen (Ü) can be set in an initial position that the second counting chain (Z2) through the frame synchronization character (R) can be switched on, which is the second counting chain (Z2) monitoring logic circuit (L4) when certain preset values are reached given, specific frame within the Uberrahmens characterizing switch positions The second Counting chain (Z2) on the third toggle switch in yours emits second switching state switching signal that the third flip-flop (KS3) in their first switching state either by the next Überrahmensynchroni zodiac sign (tJ} or a specific counter position through the output signal of another the second counting chain (Z2) monitoring logic circuit can be switched back, and that the two outputs of the third flip-flop (KS3) are connected to each one of the second inputs of the third and fourth AND circuits (U3, U4). 7) Circuit according to claim 4 between performing the method according to Pnspruch 3, characterized in that the device is made to conscience the step act those arriving from branch offices at a greater distance from the central office Pulse sequence is followed by a synchronizable clock generator. the one in normal Operation is synchronized by the step files obtained and in the case of missing step files Swings freely, that in tedem case the clock generator delivers to switch on of the shift register (SR) of the known device for obtaining the frame and Superframe synchronization characters are used to give this facility a monitoring, Counting and switching device is assigned, with the task of determining the lack of the frame, possibly also the superframe synchronization characters a predetermined period of time either the facility for To switch the acquisition of the frame and superframe synchronization characters in the branching device in such a way that that it generates the missing characters itself, or that in the terminal device of the To switch on the existing synchronization character generator. B) circuit according to claim 4 for performing the method according to claim 3, characterized in that the device for obtaining the step act from those arriving from branch offices at a greater distance from the central office Pulse sequence a switch that delays the fall and is excited by the step files obtained with the effect of one or more flush contacts is connected downstream with the task in the absence of signals from more remote outposts and there. with the step file the coming from the central office Signals obtained step clock (T1) to the transmitting device (S) for clocking and synchronizing to switch through the pulse sequence emanating from this (Fig. 2).