DE1549048C3 - Process for the detection and correction of falsified operating conditions in message transmission systems with automatic repetition - Google Patents

Description

a defined number of idle characters created an additional criterion for error detection. The number of idle characters received is checked in the ARQ receiver and one if there is a discrepancy Correction carried out (DT-AS 1 249 322).

This process has the disadvantage that the technical effort is not insignificant. There are next to that On the ARQ receiving side, the required character memory also has complicated facilities for synchronization of the space character blocks are required. On the ARQ transmission side, the Sending the space characters its own extensive circuit can be used.

The object of the invention is to show a method which, in ARQ systems, prevents the falsification of text in Space characters and vice versa are almost completely eliminated.

This object is achieved by the features specified in claim 1.

The new method has compared to the proposed The method of sending blank characters in blocks has a particularly low technical level Expenditure. The ARQ transmitter remains completely unaffected, so that only in the ARQ receiver an additional input for the request to repeat when a change in the operating status is detected is needed. Another advantage of the method shown is that it is automatic Correction of a text character that has been forged into a space or one that has been forged into a text character Space character.

The process makes the corruption of text into space characters and vice versa almost completely eliminated if a repetition process is carried out as a precaution every time the operating status is changed is initiated. A change in the operating status is recognized in the ARQ receiver with the help of a so-called operating state memory. So that every time you change text in spaces and vice versa dissolve the repetition processes initiated by this, this operating state memory must depending on the position of the acknowledgment in the repetition cycle of the ARQ receiver, can also be controlled. To distinguish between a wanted one and an undesired change in the operating status, successive repetition cycles, initiated by this change are counted. Depending on the position of the counter, additional Retry requests can be blocked or released.

Details of the invention are based on an advantageous embodiment shown in the figures is shown, explained.

F i g. 1 shows the block diagram for the non-retrievable operation of a telex subscriber at the sending end in an ARQ system.

F i g. 2 shows the block diagram for the detection and correction of falsified operating states according to the invention.

In the known ARQ system, a query is initiated if a step group other than the permitted one is received (code or parity error) or if a certain distortion value is exceeded. The inquiry is initiated by a signal RQ (request signal) sent to the remote station. This character prevents further retrieval of the message from the subscriber and at the same time causes a renewed transmission of the characters last sent, including the character that was disturbed. This retransmission is initiated by a signal RQ (request signal).

The basic idea behind the new procedure is to initiate a repetition process for every change the operating status in the ARQ device. So not only does every falsification of text lead to space characters and vice versa, but also any switching from the unoccupied one intended by a subscriber or occupied state to the state »text transmission« and vice versa to a repetition. This is but not a hindrance, since the operating mode switchovers in general only take place at the beginning and end of a message broadcast and thus the efficiency of the message flow, based on the Number of repetitions, only imperceptibly influenced. The switchover of the Permanent disconnection to the status »text transmission« and vice versa in the case of non-retrievable operation from the telex subscriber.

F i g. 1 shows the block diagram for the non-retrievable operation of a telex subscriber. In this operating mode, a retrievable buffer memory ZS is interposed between the teletype subscriber FT and the ARQ system. The characters are retrieved from the buffer memory by triggering pulses that are delivered via line 1. However, the speed at which the telex characters enter the buffer memory is generally slower than that at which the characters are interrogated by the ARQ device in the event of undisturbed transmission. In this way, pauses (/ J characters) often arise between the continuously retrieved text characters until a new character is available in the buffer memory. Due to the method of repetition initiation when switching from text to idle characters and vice versa, however, the query from this retrievable buffer memory is blocked with every change of operation, so that some new characters get into the memory during this time. The result is that the number of pause states on the transmission path decreases. The efficiency of the message flow is not influenced in the case of undisturbed transmission, since, viewed over a longer period of time, only the transmission of idle characters is replaced by repetition processes.

F i g. 2 shows the block diagram for the detection and correction of falsified operating states. The recognition of an idle character within a continuous text transmission or of a text character during the ß or character transmission takes place in the ARQ receiver with the aid of a so-called operating state memory BS. This element, which is shown in FIG. 2 is shown as a flip-flop, stores the operating state for one character length. If idle characters (+ ß) are received, the operating state memory is in one position, ie a voltage is output at output I. In the case of text characters, the operating status memory is in the other position, with a voltage now occurring at output II. The gates G \ and G2 are each supplied with a preparatory voltage, namely when idle characters (<% + β) occur at the terminal LZ a voltage, while with text characters at the terminals TX a voltage. The position of the memory BS is compared with the voltages in the gates GZ and G4 arising at the output of the gates Gl and Gl , so that with every change in the operating state at the output

of the gate G5 a voltage appears which, when the gate G6 receives a voltage from the counter VVZ and is thus prepared, triggers a repeat request at the output A.

It should also be noted in which distribution cycle of a repetition cycle the acknowledgment EQ signal falls. There, in a 4-repeat cycle ack - / (fall in short-circuit operation in the third quarter or during normal operation in the fourth quarter of the repeat cycle for the first case, in addition to the Einspeicherimpuls at terminals LZ or TX for the operating state storage BS must?. be blocked after receipt of the acknowledgment flQ character until the end of the repetition cycle. Without this measure, the initiated repetitions would no longer be resolved in the event of an intentional switch from text to idle characters and vice versa. This is achieved by a blocking circuit SB for the operating state memory BS At the input Q of the blocking circuit SB, which is designed as a bistable multivibrator, is the received acknowledgment /? (? - character that controls the flip-flop to the state I, so that the gates Gi and Gl are blocked without preparation voltage and thus The toggle switch SB only switches to position II when the distributor revolutions outside of repetitions n take place. If this is the case, a voltage appears at the input V, as a result of which the flip-flop switches to position II, so that the gates Gl and Gl are again provided with a preparatory voltage.

Another sequence of characters that has to be observed is that individual real busy or pause states (j3 characters) result within a text sequence, as already mentioned for subscribers without directly accessible operation. Since the j9 character received undisturbed is sent again from the transmission memory of the ARQ device, the repetition processes would no longer be resolved. For this reason, one or more successive repetition requests that occur due to a change in the operating state are counted and then suppressed by this counting device. This is done by the counting device ( WZ) for the repetition cycles, which blocks gate G6 when a certain count is reached and thus prevents a repetition request. The counting device WZ only counts repetition requests that follow one another.

When using key devices via ARQ links, corruption of the request signal (RQ) required by the repetition in a text combination also leads to a loss of the key phase. This forgery can be additionally secured by sending multiple A? (? Signals.

1 sheet of drawings

Claims (9)

Claims: Position (I) blocks the gate arrangement (Gi, GI) for storing the operating state (LZ, TX). 1. Method for the transmission of binary coded message characters with error detection and Repetition of the disturbed characters through an automatic query (ARQ system) with recognition and correcting the falsified operating states, characterized in that when there is a change from idle mode to message transmission mode or vice versa, a repetition process is triggered by the receiving side that the path on the receiving side a change in the operating state, repeated requests triggered immediately one after the other are counted and that a new repetition process at a certain count is prevented by a change in the operating status. 2. The method according to claim 1, characterized in that the operating state for a certain Duration is stored that the stored operating state with the currently prevailing Operating state is compared and that if the two operating states are unequal one Retry request is triggered. 3. The method according to claim 2, characterized in that the repeat requests are counted in a counting stage (WZ) and that when a certain number of immediately successive repeat requests is reached, the triggering of a further repeat request is blocked for a certain period of time. 4. The method according to claim 3, characterized in that when an acknowledgment - /? C character is received, the storage in the operating state memory (BS) is blocked for the duration of the repetition cycle and that the storage is released when manifold revolutions occur outside of repetitions . 5. The method according to claim 1, characterized in that a certain number of RC characters is sent out and that the RC characters are counted and evaluated in the receiving device. 6. The method according to claim 5, characterized in that at least one evaluation device a /? C character is recognized and evaluated. 7. The method according to claim 6, characterized in that the number of transmitted RC characters results depending on the cycle duration and the transit time between the sending and receiving points. 8. The method according to claim 7, characterized in that the operating state is fed via a gate arrangement (Gl, G2) in a trigger circuit (BS) , that the output voltages of the trigger circuit with the operating states (LZ, TX) in a further gate arrangement (G3, G4) are compared and trigger a repeat request if they are not equal. 9. The method according to claim 8, characterized in that a flip-flop (SB) is controlled by the acknowledgment ÄC character (Q) and the distributor circuits outside of repetitions (V) and that the flip-flop (SB) in one subject of the invention is a method for the transmission of binary coded message characters with error detection and repetition of the disturbed ones ίο characters through an automatic query (ARQ system) with detection and correction of falsified operating conditions. In the case of frequently occurring malfunctions, either systems with error detection and repetition of the disturbed characters through automatic query (ARQ systems) or systems with automatic reconstruction of the forged characters at the receiving location (ARK systems) are used for teletype transmission. While the ARQ systems require a permanent four-wire connection for queries, the ARK systems manage with a two-wire connection and are therefore used on unidirectional connections. In start-stop operation, malfunctions in the start-up or blocking step often occur, resulting in an increased probability of errors in the system. Therefore, the telegraphy transmission system is operated synchronously in general, and particularly in the case of radio transmission. Systems with error detection and repetition of the disturbed characters through automatic query (ARQ systems) are used for the transmission of telex characters. In order to be able to recognize disturbed characters on the radio link, it is known that the usual telex code (CCITT, No 2) with five steps per character must be converted into a code (e.g. 7-digit code) with sufficient redundancy. In Telex operation, in addition to the actual transmission of messages, there are also pause states that are characterized in the Telex network by a continuous stream of characters (when the connection is disconnected) and by a continuous disconnection current (when the connection is established). Since the synchronously operated systems do not have an operational permanent state, two special signals for the transmission of the permanent criteria are provided in the transmission code in addition to the 32 code combinations for the telex writing device. These are the idle character β for the permanent separating current state and the idle character cc for the permanent character stream state. In the times when none. Message is transmitted, so one of the two empty characters can be transmitted continuously depending on the occupancy status. Are the information steps of a character on the transmission path so disturbed that despite the redundancy of the code used, the fault can no longer be recognized, a wrong character is displayed evaluated. You can easily convert a text character into a space character (aoderjS) or vice versa a space character can be forged into a text character. These invisible counterfeits work In the case of synchronous systems, this is particularly unfavorable when encrypted operation is carried out shall be. They lead to the loss of the key phase, so that from that moment on no meaningful text more can be deciphered. A method is already known which corrupts text into space characters and vice versa recognizes and then carries out a corresponding correction. Here is a multiple broadcast