DE3415936C2 - Process for the synchronized exchange of testable data telegrams - Google Patents

Abstract

When data telegrams (D) are exchanged in duplex or half-duplex mode between two stations (A, B), there is e.g. B. in an application for computer coupling the task of ensuring through suitable synchronization that the data exchange is continued in the correct time after a transmission failure, i.e. with the repetition of the last sent and falsified received data telegram (D). A method is proposed in which a synchronization telegram (S) is always transmitted to the other station (A, B) when a corrupted telegram (D, S) is received, or - after receiving a synchronization telegram (S) - the comparison two count values (ZS, ZG) makes this necessary. The synchronization telegrams (S) contain a count value (ZS), which makes it possible, by comparison with a stored count value (ZG), to determine which station (A, B) is the next station (A, B) to receive a data telegram (D) after the fault. must send. For this purpose, z. B. in each of the stations (A, B) a synchronization device (2) is provided, which is connected to a data memory (3), a receiving memory (4) and a count value memory (5).

Description

2. The method according to claim 1, characterized in that unadulterated received data telegrams (D) are acknowledged by the receiving station (A, B) with an acknowledgment telegram which contains the data of the received data telegram (D).

Ml

The invention relates to a method for the synchronized exchange of testable data telegrams according to the preamble of claim 1. Such a method can be used for the chronological exchange of Data according to a digital transmission method on temporarily disturbed transmission channels in duplex or Half duplex operation e.g. B. can be used for computer links.

Since data telegrams can be falsified during transmission, they are usually used Verifiable codes that make it possible to check at the receiving location whether the telegram was transmitted without errors. Acknowledgment procedures in which incorrectly received telegrams are repeated are also generally known be requested. Correctly received telegrams are confirmed by sending back an acknowledgment telegram acknowledged.

When it comes down to the fact that telegrams in a certain order on the receiving side for the If further processing is available, the telegrams to be transmitted can be given consecutive numbers. Such a method is e.g. B. from DE-PS 11 54 657 known. The sequence number is used for this Procedure for the receiving station as an identifier as to whether the sending station will send out the next data telegram or whether it will repeat a previous data telegram because an error occurred in the transmission was. However, the method has the disadvantage that in the event of a disturbance in the regularity of the sequence numbers such as with a simultaneous disturbance of the transmission and reception ^ anals can occur, the synchronous operation between the transmitter and recipient is lost.

This disadvantage is avoided by a method described in DE-PS 28 12 668 in which aen telegrams individual names can be assigned. This allows using a previously established and based on identical on the sending and receiving side Name list, a clear classification of telegrams can be made.

Another method for the transmission of messages with repeated transmission of disturbed parts of the message is known from DE-PS 23 50 669. With this method, the messages are divided into characters of the same length divided with several drawing elements. The number of characters or groups of characters in one to be sent Telegrams are counted on the send side and the counter reading is inserted into the send telegram. Receiving side the characters or groups of characters contained in the telegram are also counted and with that in the telegram transmitted meter reading compared. The method is suitable for checking the complete Transmission of a message telegram, but not to ensure a specific sequence of message telegrams.

Also the previously mentioned: Methods are less suitable for systems in which in previously unknown The order of data must be transmitted in both directions, but it must be strictly adhered to the sequence in the telegram transmission arrives in both directions. Such a case is e.g. B. at coupled computer systems. It would be very time-consuming to walk each in the opposite direction to provide ongoing telegrams with an identifier that enables coordination also in the case of Transmission interference enables and synchronous operation, e.g. B. in the form of some kind of handshake procedure to resume. On the other hand, the omission of any marking leads to a Transmission disturbance the synchronous operation is disturbed. Often both directions are in the event of a transmission failure disturbed, as a result of which not only user data telegrams but also request and acknowledgment telegrams are falsified and thus there is no reference point for synchronization after the end of the fault.

The invention is based on the object of a simple method for synchronizing a data exchange indicate in duplex or half-duplex operation that a consistent and Seamless continuation of the 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 through an identifier of the individual Data telegrams is loaded. The number of consecutive

the subsequent faulty transmissions will be per transmission direction detected separately and can, for. B. evaluated statistically or to control a channel switch can be used in the event of insufficient availability of the channel currently being used. According to an advantageous Embodiment, correctly received data telegrams are acknowledged with the help of an acknowledgment telegram that contains the data of the received data telegram and allows an exact comparison in the station that sent the data telegram.

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

It shows

1 block diagram of a device for carrying out the method according to the invention,

Fig. 2 Example of a sequence of telegram transmissions according to the method according to the invention.

FIG. I shows a station A and a station B which are connected to one another by a transmission link 1. A transmission route 1 for duplex operation is shown, with telegrams being able to be transmitted in both directions at the same time. However, the invention is also suitable for half-duplex operation, where telegrams can only be transmitted alternately in one or the other direction. The stations A, B have the same structure and each contain a transmitter 5 and a receiver E, a synchronization device 2, a data memory 3 for data messages to be sent, a receive memory 4 for received messages and a count value memory 5 for count values ZG, the function of which is explained below will. The transmitter 5 and the receiver E of a station A, B are each connected to the memories 3, 4, 5 via the synchronization device 2.

A transmission cycle begins with ζ. B. in station A from the data memory 3 a data part D is read out (but is not yet deleted there) and transferred to station B. In station B , the incoming data telegram D is checked by the synchronization device 2 and stored in the receiving memory 4. If the incoming data telegram D is recognized as correct, station B acknowledges 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 receiving memory 4. If the data telegram D is received correctly, the station A interprets this as an acknowledgment of a correct transmission and accepts the next data telegram D to be sent into the data memory 3.

The acknowledgment can, however, also take place by means of a special acknowledgment telegram, which is sent e.g. B. contains the content of the data telegram D to be acknowledged.

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

Receives e.g. B. the station B a disturbed telegram D, the synchronization device 2 generates a synchronization telegram S in the station B , which is transmitted to the station Λ. The synchronization telegram S is to be understood as a request telegram. Namely, it prompts the other station - in this case A - to do so. to repeat the data telegram O last sent. The synchronization telegram j contains a transmitted count value ZS , which is formed by the synchronization device 2 by removing the stored count values ZG from the number memory 5 and increasing it by the value 1. After the synchronization telegram S has been sent , the synchronization device increases the count value ZG in the counter value accumulator 5 by the value 1 and thus to the value of the count value ZS that has just been sent. If the problem persists. - Station B receives falsified telegrams several times in succession, namely first a falsified telegram D and then several falsified synchronization telegrams 5, and synchronization telegrams S are generated and transmitted to station A each time. the

: <· Synchronized telegrams S each contain a count value ZS increased by the value 1.

Receives e.g. If, for example, station A receives a synchronization telegram 5 that has been recognized as correct, then synchronization device 2 must determine whether station A is now

- must send their data telegram D repeatedly, or whether they must first request station B to repeat their data telegram last sent so that the sequence of data exchange is maintained. This decision is made in that the synchronizing device 2

i '· - the count value ZS in the received Sy .-. aronized telegram S with that in the count value memory ZG , with

- if the counter value ZS in the received synchronization telegram ZS is equal to or less than the stored one

> ZG value is, another synchronization telegram 5 is sent, or

- if the count value ZS in the received. Synchronization telegram S is greater than the stored count value ZG , the data message sent last at the start of the fault

. " :, legram D is sent repeatedly.

Fig. 2 shows an example of a sequence of telegram transmissions. The following are entered in the columns from left to right: The cycle number of the telegram transmissions, the contents of memories 3, 4, 5 of station A, the

, - Type of telegrams D, S on the transmission path 1 and the contents of the memory 3, 4, S of the Siaiion S.

An undisturbed transmission of a data telegram D from station A to station B and vice versa is entered as cycle number 1. The data storage

^ n rather 3 a data telegram D taken from station A , transmitted and stored in the receive 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 have been set to the value zero in both stations A, B with the transmission of a data telegram D.

Station A sends in cycle number 2

5ii Data telegram D that station B receives in a falsified manner. A falsely received telegram D, S is entered in the receive memory 4 with an X in each case. Station B replies with a synchronized telegram in 5. which contains a count value ZS = 1 increased from zero to one. The Zälilwert ZG stored in station B is also incremented from the value zero to the value 1. Station A receives the synchronization telegram 5 falsified.

In cycle number 3, station Λ therefore also generates a synchronization telegram 5. that from station B

you in turn is received incorrectly, station B then sends a second Synchronisierielegramrt? S with the count value ZS = 2. which arrives in station A again incorrectly *. The contents of the count value memories 5 have been increased by a value of 1 in both stations.

In cycle number 4, station Λ sends another synchronization telegram S with a numerical value ZS = 2. Among other things, this telegram is also received incorrectly, station B sends a third synchronization telegram S with the

Count value ZS = 3. d; is is received correctly by station Λ. By comparing the count value ZS = .1 contained in the received synchronization telegram S with the count value ZG = 2 stored in station A , station / I determines that the count value ZS = .1 received is greater than the count value ZG = 2 stored by it. It follows that station A has to send the last data telegram I) repeatedly.

This happens in cycle number 5, whereby station A repeatedly sends the data telegram D already sent in cycle number 2 and sets the counter memory 5 to the value ZG = (I. Station B also receives this telegram falsified and sends a fourth synchronization telegram 'S'. that arrives incorrectly in station / I.

In cycle number 6, station A sends a synchronization telegram S with the count value ZS - 1, which is correctly received by station R. By comparing the received 7: ihhverts ZS = 1 with the count value ZG = 4 saved in cycle 5, station B determines that it has to send another synchronized signal (with ZS = 5). to achieve a repetition of the data telegram sent by station A in cycle number 2. The synchronization telegram S is correctly received by station Λ and it is determined by comparing the received count value ZS = 5 with the stored count value ZG = 1 that station A must next send a data telegram D repeatedly.

In cycle number 7, station A then sends a second repetition of the data telegram D from cycle number 2 and sets the counter value memory 5 to the counter value ZG = 0. Station ß receives the data telegram D correctly and acknowledges this by sending its own data telegram D. .The counter value memory 5 in station B is also set to the value ZG = 0. Station A receives the datertelegrpmm D nightly.

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

In cycle number 9, station A sends a first synchronization telegram S and sets the counter value memory

J aUI den Z.aiimwii .tw - ι. JiJIiVIi w i.im] / iuiiki vj «-

Telegram S falsified and therefore also sends a first Synchronisiertelegramm S. the station A receives correctly. By comparing the received count value ZS = 1 with the stored count value ZG = 1, station A determines that the count values ZS and ZG are the same, which, due to the rule mentioned above, means that station A must send a synchronization telegram S again in the next five cycle.

in cycle number 10, station A therefore sends a second synchronization telegram 5. that station B receives 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 the data telegram D sent in cycle 8 must be sent repeatedly by station B . The data telegram D is received correctly in station A.

For this purpose 2 sheets of drawings

Claims (1)

Patent claims: 1. Procedure for the synchronized exchange of testable data telegrams between two stations, * each containing a counter over a transmission path in duplex or half-duplex mode, characterized in that a consequent resumption after a transmission failure an exchange of the data telegrams (D) ι 'takes place by a) the station (A, B), which receives a falsified data telegram (D), sends a testable synchronization telegram (S) and also sends a further synchronization telegram (S) after receiving a falsified synchronization telegram (S), wherein aa) the synchronization telegrams (S) contain a count value (ZS) which indicates the number of 2t> synchronization telegrams (S) sent one after the other by the station (A, B) since the last transmission of a data program (D) and where ab) the counter value (ZS ) sent with a synchronization telegram (S) is stored in the sending station (A, B) as a stored counter value (ZG) and is always reset to zero when this station (A, B ) sends a data telegram (D) and that b) the station (A, B), which receives a synchronization telegram (S) correctly, compares the count value (ZS) contained therein with the count value (7G) stored in the receiving station (A,} n B) , and ba) if the count value (ZS) in the received synchronization telegram (S) is equal to or less than the stored count value (ZG) , sends another synchronization telegram (S). '. f. or bb) if the count value (Z) in the received synchronization telegram (S) is greater than the stored count value (ZG) , the last data telegram (D) sent is sent again. in