DE2659533C2 - Method for the transmission of messages in a telecommunications system with a large number of subscriber stations - Google Patents

Description

The invention relates to a method for message transmission in a telecommunications system with a plurality of subscriber stations and a clock generator, the subscriber stations and the clock generator are connected to a loop-shaped common time division and the clock generator periodically transmits synchronization blocks to which the subscriber stations synchronize and subdivide their time interval into a number N of time channels.

A number of proposals have become known as to how such time-division multiplex message systems can be implemented with multiple access and a time-division multiple transmission path closed in a loop. The arrangement shown in FIG. Is 1 and in the 7 ".S the subscriber stations and TG represent a central clock generator. In order to avoid that transmitted messages circulate continuously on the loop, the messages are respectively taken out to their destinations by the receiving subscriber station from the zeitmul · tiplexen message stream .

For addressing the messages, i.e. the identification of the receiving subscriber station, there are two possibilities:

1. Each message block is preceded by an address block. This is for example in the DE-OS 21 51 016 described in detail. The broadcast

To the message blocks from the individual subscriber stations is only a given one Time channel grid, not but bound to a specific time channel within a time division multiplex frame on the transmission medium the.

2. The message blocks of a single message connection between two subscriber stations are in each case on precisely defined time channels within the time division multiplex frame of the transmission transmission medium, as in the DE-AS 18 04 624 described. The serial number of the time channel used for the transmission is therefore, when a connection is established, it is the destination address and a separate address block at the same time unnecessary.

However, both methods have the disadvantage: In the first method, mutual blocking of the transmission path can occur, if there is no static one

w Allocation of news sources and sinks is available (cf. B. Avi-Itzhak "Heavy traffic characteristics of a circular data network". Bell Syst, techn. J. 50 (1971), pp. 2521-2549). As a result of this state, there are sometimes considerable temporary stores in the partial

J "> subscriber stations necessary. In the DE-OS 23 32 599, the loop runtime changes constantly. So that is in both If a sequence of equidistant message blocks from the message source is received at the lowing subscriber station no longer occur equidistantly. This leads to high transmission speeds. cause considerable difficulty in Demultiplexing the blocks from the time-division multiplexed message flow. Through the attached address is In addition, the share of the transmission capacity that can be used for message transmission is considerable reduced.

The aforementioned difficulties are completely overcome with the second method. However , for reasons of time channel synchronization, the loop runtime must be a whole multiple of the frame duration. According to the proposal in DE-AS 18 04 624, this is achieved by inserting a buffer memory. The use of buffer memories according to DE-AS 18 04 624 is a sensible option for loop systems with a medium transmission rate and a not too large number of time channels per frame. However, if the transmission rate increases above IO MHz and thus the number of PCM time channels in the frame

^h0 150, the effort for the buffer storage and the necessary control is quite considerable.

It was the task leading to the invention. the effort for caching increases considerably to reduce.

"'' The task is solved as in the claim! described.

The storage requirement is reduced by the fact that the loop runtime is no longer limited to

Multiples of a time division multiplex frame is supplemented by buffer memory, but only to whole multiples of a time channel. In the simplest case, for example, the delay compensation is only a fraction of a time channel. This time alignment, as proposed in DE-AS 18 04 624, made in ^T aktgenerator TG. Since message blocks that were transmitted in a time channel χ occur after the end of the loop in the time channel x + a , where a is the normalized loop delay time

- including runtime compensation with λ a! S absolute 10

Loop running time and To as the duration of a time channel is an integer multiple of the time duration of a time channel, certain rules result when setting up a connection within a loop system according to the invention, which are given in the following description of the system.

The method according to the invention will now be explained in more detail below.

The clock generator TG sends out equidistant synchronization blocks which each mark the beginning of the time division multiplex frame. Synchronization blocks that have circulated once in the loop are suppressed by the clock generator TG. Each subscriber station TS synchronizes itself on this synchronized 'öcke. In addition to the synchronization blocks, the clock generator can send out further clock pulses, for example at the beginning of each time channel (cf. KD Schenkel "An integrated 300 Mbit / s time division multiplex message system with central switching", Message Techn. Z. 27 (1974), p . 283-291) in order to facilitate the recovery of the transmission clock in each subscriber station. With the help of the synchronization blocks and the transmission cycle, each subscriber station can subdivide the time-division multiplex frame into a predetermined number of equal-sized time channels and identify these time channels as counting within a frame.

For example, a frame contains N time channels with the order number \ ... N, with the synchronization block being transmitted in time channel 1, and the total normalized loop delay including delay compensation amounts to a time channels, with the standardized loop delay a being significantly shorter than the frame duration.

If a subscriber station, for example Ti 1 in Fig. 2, wants to set up a communication link with another subscriber station TS2, it looks for two free time channels / 'and; 4-a within the time division multiplex frame and occupies the time channel / with a call block that contains the address of the Subscriber station TS " contains. All subscriber stations, including those involved in another communication link sir.d, check the call block circulating in the time channel /. Subscriber station TS2 detects the call. Removes the call block from the time channel and adds a response block in its place one that can either contain a busy signal (if TS2 is already involved in another communication link) or an idle signal (if TS 2 is free). This response block runs in the time channel / to the end of the loop, goes through the clock generator TG and now appears unchanged i is assigned the TS 1 Tci'nehmerstaiion takes therefore, in a time channel to which the i + Ordnungsnummcr. the response block to the / routing channel i + a. The time channel 1 + .1 is thus available for further connections for subsequent subscriber stations. Once the connection has been established, the message blocks (without additional addressing) are transmitted in the same time channels / or i + a. When the connection is terminated, no more message blocks are transmitted in the time channels / and / + a , and these time channels are thus free for other use. To differentiate between call and control blocks on the one hand and message blocks on the other hand, signaling characters can be used at an agreed point within the

to time channel (cf. above article by K .. D. Schenkel in Nachrichtenentechn. Z. 27 (1974), pp. 283-291). By sending an information block in a time channel χ and removing a block in time channel x + a by the subscriber station setting up the connection (or removing a block and sending a block in time channel χ by the called subscriber station), mutilated blocks are removed from the taken out participating in a transmission subscriber station itself.

Because of the normalized loop runtime a, the last time channels (N-a + \, Na + 3 ... / V) of the time division multiplex frame must not be used for the transmission of information between subscriber stations, as otherwise a disruptive overlay with the contents of the time channels X ... a would occur. However, these time channels can be used for "general" messages to all subscriber stations that are sent out by the clock generator.

Jo The normalized loop runtime a , which is initially unknown to the individual subscriber stations, is determined by the clock generator TG and this value is then sent to the individual in an agreed time channel (preferably in one of the time channels N ~ a + \ ... N)

y, subscriber stations transmitted.

The measurement of the normalized loop transit time a is carried out using the exemplary switch shown in FIG. 3a and the pulse schedule of FIG. 3b explained. The synchronous generator SyncG generates the synchronization block and, if necessary, further clock pulses to support the transmission clock recovery in the individual subscriber stations. By means of the signal 5VW, which characterizes the time channel 1 and resets the counters ZX and Z 2, both counters are closed

■ * ■ '> of the first time channel started. Counter ZX emits a signal / 1 at its output when a time channel has ended. The time channel counter Z 2 is incremented with this signal IX.

If the from the synchronous generator SyncG via the

"- ¹¹ multiplexer M on the transmission line L given synchronization block at the end of the transmission loop has completely entered the shift register chain 5 t, the synchronization block recognition circuit UX emits a pulse / 2 that the current counter

*>"> Was the counter Zl and Z2 reads in the memory 52 and 53rd The count of Z 2 now represents the normalized loop delay a represents the counter Star while i is used by Z1 to a per se known decoder D of the Gate U 2

bo ... Uk and thus shorten the loop runtime to a whole multiple of a time channel. During each time frame, the content of the memory 53, the normalized loop delay time a contains. transmitted to the subscriber station and in turn the

^ s new loop runtime measured. The circuit has the advantage that disturbed sync blocks do not lead to a corruption of the running time, since the previous value in 5 2 and S 3 is retained.

Switch A is controlled by a counter, not shown, so that it can be used during the time channels! ... a is open in order to keep the time channels N-a + \ ... N pending at the output of O 1 away from the beginning of the loop.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. A method for the transmission of messages in a telecommunications system with a plurality of subscriber stations and a clock generator, the subscriber stations and the clock generator being connected to a common closed loop time division and the clock generator periodically transmits synchronization blocks to which the subscriber stations synchronize and their time interval in a Subdivide number N of time channels, characterized in that the clock generator removes a synchronization block again after one cycle in the loop, that the loop runtime a normalized to the duration of a time channel is selected as an integer multiple of the time length of a time channel, that a Subscriber station automatically two time channels not otherwise occupied; and i + a seeks, sends out a call identifying the receiving station on the / th time channel and receives the response from the other subscriber station to this call in time channel i + a and sends out the message to be transmitted instead of the call in time channel / after the connection has been established . 2. The method according to claim 1, characterized in that the time channels N— a + 1 to N are not used for individual connections between subscriber stations, but for the transmission of distribution information. 3. The method according to claim 1, characterized in that the measurement of the loop runtime is carried out by the clock generator and the value a found is communicated to the subscriber stations in an agreed time channel. 4. The method according to claim 1 to 3, characterized in that all of the loop connected subscriber stations constantly the entire time division multiplex frame on ^ inen to them monitor directed call.