DE3415936A1 - Method for synchronised exchange of checkable data telegrams - Google Patents

Abstract

In an exchange of data telegrams (D) in duplex or half-duplex mode between two stations (A, B) the object, e.g. in an application for computer link-up, is to ensure through suitable synchronisation that the data exchange is continued in the correct temporal sequence following transmission interference, that is to say with the repetition of the data telegram (D) which was most recently transmitted and was received in corrupted form. A method is proposed in which a synchronisation telegram (S) is transmitted to the other station (A, B) whenever a corrupted telegram (D, S) is received, or - following reception of a synchronisation telegram (S) - the comparison of two counting values (ZS, ZG) requires this. The synchronisation telegrams (S) contain a counting value (ZS) by means of which it can be ascertained by comparison with a stored counting value (ZG) which station (A, B) must be the next station (A, B) to transmit a data telegram (D) following the interference. For this purpose, a synchronisation device (2) can in each case be provided, e.g. in the stations (A, B), which is connected to a data memory (3), a reception memory (4) and a counting value memory (5). <IMAGE>

Description

Procedure for the synchronized exchange of testable

Data telegrams The invention relates to a method for synchronized exchange of testable data telegrams according to the generic term of claim 1. Such a method can be used for the chronological exchange of Data using a digital transmission method on transmission channels with intermittent interference can be used in duplex or half-duplex operation, e.g. for computer links.

Since data telegrams can be falsified during transmission, As a rule, verifiable codes are used, which make it possible to get to the place of reception check whether the telegram was transmitted without errors. Well known are also Acknowledgment procedure in which incorrectly received telegrams are repeatedly requested will. Correctly received telegrams are confirmed by sending back an acknowledgment telegram acknowledged.

When it comes down to the fact that telegrams are in a certain series on the receiving side for further processing can be transmitted Telegrams are provided with consecutive numbers. One such procedure is e.g. from DE-OS 23 50 669 known.

There cyclic counting elements are provided on the sending and receiving sides. However, the sequence numbers determined by such counting devices are repeated in relatively short intervals, namely as soon as the highest possible count is reached is. In addition, errors in the counting mechanism or in the transmission can lead to that the synchronous operation of the sending and receiving side counter is disturbed, so that received telegrams are incorrectly accepted as correct, if the sequence number comes from another counting cycle.

These disadvantages are described in DE-PS 28 12 668 Avoided procedure in which individual names are assigned to the telegrams. This can be done with the help of a previously established and on the sending and receiving side Filed identically named list of names a clear classification of telegrams take place.

However, these known methods are less suitable for systems in which data is transmitted in both directions in a previously unknown order must be, however, it is a matter of strict adherence to the order in the Telegram transmission arrives in both directions. Such a case is e.g. given with coupled computer systems. It would be very time-consuming to identify the individual to provide telegrams running in the opposite direction with an identifier, which enables coordination even in the event of transmission disruptions and after Disruptive resumption of synchronous operation, e.g. in the form of any handshake procedure. On the other hand, the omission of any marking leads to the fact that after a transmission fault synchronous operation is disturbed. Often are namely with a transmission failure both directions disturbed, which means that not only user data telegrams but also request and acknowledgment telegrams can be falsified, and thus every reference point for there is no synchronization after the fault has ended.

The invention is based on the object of a simple method specify to synchronize a data exchange in duplex or half-duplex mode, This is a consistent and uninterrupted continuation even after a transmission disruption of data exchange guaranteed.

This object is achieved by a method according to claim 1.

Advantages of the method include: to see that the data transport is not burdened by an identifier of the individual data telegrams. The number successive faulty transmissions are separated for each transmission direction recorded and can, for example, be statistically evaluated or to control a channel switch can be used in the event of insufficient availability of the channel currently being used. According to In an advantageous embodiment, correctly received data telegrams are also included With the help of an acknowledgment telegram that acknowledges the data of the received data telegram and an exact comparison in the station that sent the data telegram allows.

A more detailed description of the invention is based on an exemplary embodiment and the drawing.

They show: FIG. 1 a block diagram of a device for carrying out the method according to the invention, Fig. 2 example of a sequence of telegram transmission worked according to the method according to the invention.

Fig. 1 shows a station A and a station B passing through a transmission link 1 are connected to each other. A transmission link 1 for duplex operation is shown, telegrams can be transmitted in the same line in both directions. However the invention is also suitable for half-duplex operation, with only alternating in telegrams can be transmitted in one direction or the other. The stations A, B have the same structure and each contain a transmitter S and a receiver E, a synchronization device 2, a data memory 3 for data telegrams to be sent, a receive memory 4 for received telegrams and a count value memory 5 for counter values ZG, the function of which is explained below. The transmitter S and the Receivers E of a station A, B are each via the synchronization device 2 connected to memories 3, 4, 5.

A transmission cycle begins with that e.g. in station A off the data memory 3 read a data telegram D (but not yet deleted there is) and is transmitted to station B. In station B the incoming Data telegram D checked by the synchronization device 2 and stored in the receiving memory 4 filed.

If the incoming data telegram D is recognized as correct, it is acknowledged station B by sending a data telegram D from station B to station A. The received data telegram D is checked in station A and stored in the receive memory 4 filed. If the data telegram D is received correctly, station A captures this as confirmation of correct transmission of the previous data telegram D to station B and takes over the next one to be sent in data memory 3 Data telegram D.

However, the acknowledgment can also be made by a special acknowledgment telegram that e.g. contains the content of the data telegram D to be acknowledged.

After such a trouble-free data exchange, the count value memories have 5 in both stations A, B the value zero. The count value memory 5 of a station A, B is always set to zero when this station A, B receives a data telegram D sends.

If, for example, station B receives a disturbed telegram D, it is generated the synchronization device 2 in the station B a synchronization telegram S, the is transmitted to station A. The synchronization telegram S is a request telegram to grasp. Namely, it asks the other station - in this case A - that to repeat the data telegram D last sent. The synchronization telegram S contains a sent count value ZS, which is obtained by taking the stored count value ZG from the count value memory 5 and increase by the value 1 from the synchronization device 2 is formed. After the synchronization telegram S has been sent, the synchronization device increases 2 increases the count value ZG in the count value memory 5 by the value 1 and thus to the value of just sent count value ZS. If the disturbance persists, the station receives B telegrams falsified several times in succession, namely initially one falsified Telegram D and subsequently several falsified synchronization telegrams S and es Synchronization telegrams S are generated and transmitted to station A each time. The synchronization telegrams S each contain a value increased by 1 Count value ZS.

For example, if station A receives a synchronization telegram that has been recognized as correct S, then the synchronizing control device 2 can be determined, whether the station A must now send its data telegram D repeatedly, or whether it must first the station B must request to repeat the data telegram it last sent, so that the sequence of data exchange is adhered to. That decision will taken by the fact that the synchronizing device 2 receives the count value ZS in the Synchronization telegram S with the count value ZG stored in the count value memory 5 compares, whereby - if the counter value ZS in the received synchronization telegram S is equal to or less than the stored count value ZG, another synchronization telegram S is sent, or - if the counter value ZS is in the received synchronization telegram S is greater than the stored count value ZG, the last one with the start of the disturbance sent data telegram D is sent repeatedly.

Fig. 2 shows an example of a sequence of telegram transmissions. In in the columns from left to right are entered: The cycle number of the telegram transmissions, the contents of the memories 3, 4, 5 of station A, the type of telegrams D, S of transmission path 1 and the contents of memories 3, 4, 5 of station B.

Cycle number 1 is an undisturbed transmission of a data telegram D entered from station A to station B and vice versa. This is the data store 3, a data telegram D is taken from station A, transmitted and stored in the receiving memory 4 of station B. Since the transmitted telegram is recognized as correct, station B takes a data telegram D from its data memory 3 and sends it to Station A, where it is stored in the receiving memory 4 and recognized as correct. the Count value memories 5 are in both stations A, B with the transmission of a data telegram D was set to the value zero the.

In cycle number 2, station A sends a data telegram D that Station B receives corrupted. A falsely received telegram D, S is in Receive memory 4 entered with an X in each case. Station B replies with a synchronization telegram S, which contains a count value ZS = 1 increased from zero to one. The one in station B stored count value ZG is also incremented from the value zero to the value 1. Station A receives the synchronization telegram S falsified.

In cycle number 3, station A therefore also generates a synchronization telegram S, which is received by station B in an incorrect way. Station B then sends a second synchronization telegram S with the count value ZS = 2, which is sent to station A again arrives falsified.

The contents of the count memory 5 are in both stations by one Value 1 has been increased.

In cycle number 4, station A sends another synchronization telegram S with a count value ZS = 2. Since this telegram is also received incorrectly, Station B sends a third synchronization telegram S with the count value ZS = 3, the is received correctly by station A. By comparing the synchronization telegram received S contained count value ZS = 3 with the count value ZG = stored in station A 2 determines station A that the received count value ZS = 3 is greater than that of its stored count value ZG = 2. It follows that station A received the last data telegram D has to send repeatedly.

This happens in cycle number 5, where station A is already in Cycle number 2 sends data telegram D repeatedly and the counter value memory 5 on the Set value ZG = 0. Station B also receives this telegram falsifies and sends a fourth synchronization telegram S, which falsifies in station A. arrives.

In cycle number 6, station A also sends a synchronization telegram S. the count value ZS = 1, which is correctly received by station B. By comparing the received count value ZS = 1 with the count value ZG = 4 saved in cycle 5 Station B determines that they are sending another synchronization telegram (with ZS = 5) must in order to repeat the data telegram sent by station A in cycle number 2 to reach. The synchronization telegram S is received correctly by station A. and it is determined by comparing the received count value ZS = 5 with the stored one Count value ZG = 1 found that station A next repeats a data telegram D must send.

In cycle number 7, station A then sends a for the second time Repetition of the data telegram D from cycle number 2 and sets the counter value memory 5 to the count value ZG = O. Station B receives the data telegram D correctly and acknowledges this with the sending of its own data telegram D, whereby also in station B the Counter value memory 5 is set to the value ZG = 0.

Station A receives the data telegram D correctly.

Station A therefore sends the next data telegram in cycle number 8 D, which is received correctly in station B. Station B sends another data telegram D, the station A receives corrupted.

In cycle number 9, station A sends a first synchronization telegram S and sets the count value memory 5 to the count value ZG = 1. Station B receives this Telegram S falsifies and therefore also sends a first synchronization telegram S, that station A receives correctly.

By comparing the received count value ZS = 1 with the stored one Count value ZG = 1, station A determines that the count values ZS and ZG are the same, which means, due to the rule mentioned above, that station A again in the next cycle a synchronization telegram S must send.

Station A therefore sends a second synchronization telegram in cycle number 10 S receiving station B correctly. By comparing the received count value ZS = 2 with the stored count value ZG = 1, station B determines that the received Count value ZS is greater than the count value ZG stored by it and therefore that Data telegram D sent in cycle 8 by station B can be sent repeatedly got to. The data telegram D is received correctly in station A.

Claims (2)

A n p r ü c h e procedure for the synchronized exchange of testable Data telegrams between two stations via a transmission link in duplex or half-duplex operation, characterized in that a) the station (A, B) which is a Receives corrupted data telegram (D), a verifiable synchronization telegram (S) sends and also after receipt of a falsified synchronization telegram (S) sends another synchronization telegram (S), whereby aa) the synchronization telegrams (S) contain a count value (ZS) that indicates the number of times the station (A, B) has been Synchronization telegrams sent one after the other after the last transmission of a data telegram (D) (S) indicates and where ab) the count value sent with a synchronization telegram (S) (ZS) stored in the sending station (A, B) as a stored count value (ZG) and is always reset to zero when this station (A, B) receives a data telegram (D) sends and that b) the station (A, B) which sends a synchronized telegram (S) correctly receives the count value (ZS) contained therein with that in the receiving station (A, B) compares stored count value (ZG), and ba) if the count value (ZS) im received synchronization telegram (S) is equal to the stored count value (ZG) or is smaller than this, sends another synchronization telegram (S) or bb) if the counter value (ZS) in the received syn- chronized telegram (S) is greater than the stored count value (ZG), the last one sent again Sends data telegram (D). 2. The method according to claim 1, characterized gekennzeichnest5 that unadulterated Received data telegrams (D) from the receiving station (A, B) with an acknowledgment telegram which contains the data of the received data telegram (D).