DE926557C - Procedure for clearing telegraphic messages - Google Patents

Description

Method for eliminating interference in telegraphic messages The invention relates to a method for eliminating interference in telegraphic messages.

It is well known that telegraphic characters are used, especially in the case of wireless Transmission, both of disturbances, one step of the telegraphic character as well as from disturbances that cannot be seen in the telegraphic sign generate existing current step, falsified. These disorders affect the individual transmission methods in different ways.

In the so-called single stream process, the separation and character stream steps are used the telegraph characters marked in a known manner, that each only for the current steps of one polarity, e.g. B. the separating current steps, transmit a signal is, while in the current steps of the other polarity, z. B. the character stream steps, the transmission of a signal does not take place. So is z. B. a method is known in, which transmit a certain frequency f to identify each isolating current while the character stream steps are marked by pauses in transmission. With this one Procedures affect the disturbances in such a way that through them a separation flow step is falsified in a character stream step or vice versa. At the single stream step such a fault cannot be easily recognized. But it is possible to secure the individual telex characters against interference. The well-known ones are used for this Coding and iteration processes.

At. In the so-called double stream method, both the separating and the character stream steps are marked by certain signals. So z. B. in the known double-tone or frequency shift keying method for each separating current step a certain frequency fi and for each character stream step a likewise certain frequency f 2 different from the frequency f i. With interference-free transmission, only one of the two frequencies can occur at a time. However, if the transmission is disturbed, a third status is still possible. This consists in the fact that either both frequencies occur simultaneously or neither of the two frequencies is present. In this case the receiving organ becomes neither in one; influenced in another sense. Is the receiving organ z. B. from a polarized relay: so this remains on the side on which it happens to be, and causes in 50% of all malfunctions of the specified type a falsification of the relevant current step.

If the disturbance affects only one of the two frequency ranges, as already mentioned, either both frequencies at the same time or neither Frequencies on. These disturbances can already be recognized at the level of the current step @will. In the following, the term disorder is used for this type of disruption Degree needed.

If a disturbance affects both frequency ranges at the same time, either a separating current step is falsified into a character stream step, i.e. the frequency f i results in the frequency f 2, or the reverse case occurs in which a character stream step is falsified into a separating current step, i.e. from the Frequency f 2 results in the frequency f i. Disturbances of this kind cannot be recognized in the individual current step and in all cases lead to an incorrect setting of the receiving device. In the following, the term disruption of a higher degree is used for this malfunction.

In the single-stream process, all disturbances have an effect, since these There are not recognizable from the individual current step, such as disturbances of a higher degree the end. In the case of double-flow processes, on the other hand, both higher disturbances and disturbances occur lower degree, on. However, the disturbances of a higher degree are essential here rarer than the lower grades.

Various interference elimination methods are now known or have been proposed. The so-called step test method uses the fact that in the case of double-current transmission, if there are no disturbances, only one of the two frequencies f i or f 2 can be present. If both frequencies or none of them are present at the same time, this is determined during the step test procedure and the telegraph symbol concerned; to which this current step belongs is marked as disturbed. It is clear that this method cannot detect disturbances of a higher degree and then delivers missing characters. In the case of telegraph characters transmitted according to the single stream method, disturbances can accordingly not be recognized at all using the step checking method. The so-called repeat processes are also known. With these, either the individual current step or the entire current step sequence forming a telegraph character is used for fault detection. So z. B. in one of the known repetition methods, each telegraphic character is transmitted several times in succession and, on the receiving side, the one selected from the various transmissions of each telegraphic character using a statistical method which is most likely not to be disturbed. The repetition methods can detect both low-grade and higher-degree disorders, but no repetition method has yet become known which detects both low-degree disorders and higher-degree disorders with complete certainty. All procedures that have become known only detect the disturbances with a certain probability.

Record the coding processes that have already become known likewise the disturbances of lower and higher degree, but only with one certain probability. In this process, the telegraphic characters are used converted into an interference-free code when it is used on the receiving end can be recognized with a certain probability; oh the received Character is disturbed or not. There are procedures that both lower disturbances Grades as well as disruptions of a higher degree with approximately the same probability.

All interference clearance procedures known so far are in view of on certain transmission properties of the transmission path or with regard to certain sturgeon species have been trained. This probably made it possible to establish interference clearance procedures to create the assumption of certain transmission properties or types of interference Have a relatively good effect, but when the transmission properties change or the sturgeon species lose their effectiveness very quickly. It is obvious that these interference elimination procedures developed for special conditions are not are universally applicable.

In order to increase the effectiveness of the individual interference clearance procedures, Kombin.atiortenn various such processes have already become known to one another. However, none of the previously known combination processes has resulted in a satisfactory one; Result led. This is mainly due to the fact that the disturbances in divided unilateral and bilateral. Under one-sided Disturbances are understood as those that only change the current steps during a transmission one polarity, e.g. Falsify the character stream steps. As bidirectional Interferences, on the other hand, are referred to as interferences that occur during a transmission the signs all also falsify the isolating current steps. If you now combine a process that grasps one-sided disturbances, with one that also opposes z, # vei, sided Interference is effective, an increased interference elimination is achieved, but there is this only in the cumulative effect of the two individual proceedings. That these combined Failure to enforce proceedings is due in large part to the fact that the The effort is usually unacceptably large, or it depends on the message flow through this procedure is degraded too much.

The invention is based on the object of an interference elimination method to create that without reducing the flow of messages a greater amount of interference than any of the previously known methods or one of the previously known combinations same delivers.

The invention is based on the new knowledge that a combination one against one-sided disturbances with one against two-sided Interference-directed method can not achieve this goal, but that according to the most essential feature of the invention is an interference elimination method that against Disorders of a lower degree are directed at the same time as against disorders higher degree can be applied in a targeted manner and the fault indicator in dependence must be operated by both interference clearance procedures.

Since it is only possible to use a double-flow process to record both low-level and higher-level disorders, the invention is limited to such methods. The following is an exemplary embodiment the combination of a step test with the so-called seven step: eweighing process described.

With the step-by-step weighing method, the tele of the international telegraph alphabet in seven stream steps Stream steps converted, which are chosen so that with each telegraphic character the ratio of separation to cell flow steps 3: .a. is. When receiving the Telegraph characters are each of the same e.g. B. by means of a weighing device checked for this 3: 4 ratio and, if there is a deviation from the target ratio is detected, the teletype character concerned is marked as disturbed. According to a further feature of the invention, in addition to this method a device is provided which records each individual flow step of a telegraph character on the basis of the step test procedure and also in the event of faults of a lower degree which actuates the teletype character as disturbed device. At the The disrupted current step is identified in a seven-step weighing process via the so-called fault relay.

In; Figs. i and 2 are circuit arrangements for performing the Shown method according to the invention.

In the circuit arrangement of FIG. 1, the telex characters are received by the receiving keypad ET , which is shown only symbolically. By this, when receiving the frequency fi, the z. B. Is to represent separating current, the relay R i energized. If the frequency f 2, the z. B. should mark stream of characters received, the relay R 2 is energized. According to the received frequencies, when the relay R i is excited, its contact rii is put to positive potential and when the relay R2 is excited, its contact r21 is put into negative potential. The contacts rii and r21 are connected to the input of the receive distributor via the resistors W i and W 2. The distribution contacts ka to kg sense the position of the relays R i and R2. Is z. If, for example, the relay R i has been excited by the frequency fi, the contact rii is at positive potential, and the distributor contact, which is scanning at this moment, establishes this positive potential. Assuming that the distributor contact ka has carried out the scanning, the positive potential is applied to the storage relay RA and energizes it. According to the seven current steps of each telegraph character, seven sensing contacts kca to kg are provided with their associated storage relays RA to RG. The contacts ra to rg of the storage relays RA to RG are set according to the polarity of the seven current steps received. The weighing device A now determines in a manner known per se whether the separator and character flow ratio in the received telex was equal to 3: .4. If the balance shows that the target ratio does not exist, the fault relay RX is actuated. As is known, this relay can be used in various ways. Either the received telex code is marked as disturbed by the malfunction relay RX, i.e. a so-called smear symbol is printed, or the relay RX prevents the received telex code from being recorded and automatically causes the transmission station to repeat the character that has just been received. The contacts i2 and 7:22 of the relays R i and R2 are also actuated by these relays when the frequencies f i and f 2 are received. These two contacts are used to record low-level disturbances. If only the frequency f i or f 2 is received, either only the relay R i or only the relay R2 is energized. In this case, one of the two contacts r 12 and r22 is in the opposite position to that shown. There is no fault of a lower degree, and the positive potential at contact r 12 is not switched through to fault relay RX, so that it remains unexcited. If, on the other hand, both frequencies, ie f i and f 2, occur, the two relays R i and R2 are excited at the same time, and the contacts r 12 and r22 are in the opposite position to that shown. As a result, positive potential is applied to the relay RX via these two contacts after the contact ki has been closed, which excites it and triggers the measures already described above. The contact ki advantageously closes at the same time as the seven sensing contacts of the distributor. As is well known, the individual stream steps of the teletype characters not for their entire duration, but only for a shorter period of time, e.g. B. with step center sampling only in the middle of the current step, it is achieved that the interferences between the sampling times remain ineffective. The contact ki can also serve to hide the desired channel in multi-channel devices. The same conditions exist if none of the frequencies fi or f 2 is received. Then neither the relay R i nor the relay R 2 is energized, and their contacts r 12 and r: 22 are in the one shown in FIG. Position, so that a positive potential is also applied to the fault relay RX. By means of this simple circuit, disturbances of a low degree are completely recorded.

In the event of a disturbance of a higher degree, a current step of one polarity becomes in a. those of the other polarity are falsified. In this case, the weighing device A determines a deviation from the target ratio in a manner known per se, whereby this Disturbances of a higher degree are also recorded.

There is a certain disadvantage in the embodiment of FIG in that, as well as when using the step test method alone, unnecessary many smear marks or queries come about. The one shown in FIG Circuit arrangement avoids this disadvantage. The step checking device initiates this according to a further feature of the invention only then the imprint of a smear mark or a query if at least two faults are lower within a character Degree can be determined by the step checking device.

The circuit arrangement of Fig. 2 corresponds with respect to the receiving and selection circuit entirely of the circuit arrangement of FIG. Since these parts are in Fig. 2 have not been shown again, the same must be supplemented by Fig. I think. The complete circuit is obtained if the second excitation circuit is shown in FIG of the fault relay RX replaced by the circuit of FIG.

The mode of operation of the circuit arrangement of FIG. 2 is as follows: If no interferences of a lower degree are received within a frequency notation, the contact r41 is in the position shown in the figure. The positive potential at contact r 12 is not switched through to relay R 3 for the reasons mentioned for FIG. I, so that it remains unexcited. In the case of the first disturbance of a lower degree, as already explained for FIG. I, the positive potential at contact r 12 is switched through to relay R 3 via contacts r 12, r22, ki and r41. As a result, the relay R 3 is energized and its contact r3 is switched to the opposite position shown in FIG. A positive potential is now applied to the capacitor C via the contact r 3, as a result of which it is charged. After this first disturbance has ended, the relay R 3 is de-energized again, and the contact r 3 returns to the position shown in FIG. The positive potential of the capacitor C at the contact r 3 is now applied to the relay R4, and the capacitor C is excited by the discharge. As a result, the contacts r41 and r42 are turned over in the opposite position to that shown in FIG. Contact r42 is a self-holding contact that prevents relay R4 from dropping out after the capacitor has discharged. The connection between contact r22 and the fault relay RX is now switched through via contact r41.

If there is no further code on the same telex code If the disturbance of a lower degree is more evident, then the one at contact r 12 becomes positive Potential, as explained for FIG. I, not switched through to relay RX. Every however, further disturbance of a lower degree causes this potential to be switched through to relay RX and thus excitation of the same. After finishing each teletype code the contact r i is opened, whereby the relay R 4 drops out and its contacts r41 and r42 are put back in the position shown in the drawing.

As calculations and tests have shown, are with the invention The method of the exemplary embodiments reduces the number of errors by one or more powers of ten lower than when using the seven-step weighing method alone. Would if only the step test method is used, the number of errors would be intolerable high. Despite the unexpectedly large reduction in the number of errors, the effort relatively low. In the circuit arrangement of FIG. I there is only one additional Distribution contact necessary, while the circuit arrangement of FIG. 2, two distribution contacts and contains two relays in addition.

The invention is not limited to the embodiments shown in Figs limited. Rather, these can be changed in any way. In particular is it z. B. also possible, the relay circuits of Fig. I and 2 by after the same principle working tube circuits to replace.

Claims (6)

PATENT CLAIMS: i. Procedure for the elimination of interference by telegraphic, according to messages transmitted by a double stream method, characterized in that a disruption clearance procedure that detects low-level disruptions with a disruption clearance procedure, which also includes disturbances of a higher degree, applied together and. the fault indicator is operated depending on both interference clearance procedures. 2. Procedure according to Claim i, characterized in that a step test method together with a Encoding method that captures disturbances of a higher degree is applied. 3. Procedure according to claim i, characterized in that a step test method together with a repetitive procedure that captures disturbances of a higher degree will. q .. Method according to one of Claims i to 3, characterized in that the telegraph characters received by each of the interference clearance methods used checked for malfunctions and, if one of the procedures causes a malfunction is found, the telegraph mark in question is marked as disturbed will. 5. The method according to any one of claims i to 3, characterized in that the telegraph character received by each of the interference clearance methods used are checked for malfunctions, but only then a disturbed teletype character is marked as disturbed due to the examination of the disturbances of a lower degree, if by means of this method a certain minimum number, preferably at least two current steps of this symbol were recognized as disturbed. 6. Procedure according to one of claims i to 5, characterized in that the check for faults lower degree takes place only during the duration of the scanning of the current steps.