DE958390C - Circuit arrangement for transmitting a service mark in rhythmic telegraph systems - Google Patents

Description

ISSUED FEBEUARY 21, 1957

is used

In telegraph systems in which the telegraph symbols each consist of a fixed number of steps, of which the first (start step) and the last (stopping step) usually having fixed opposite polarities often consists a need to transmit a service mark to secure telegraphic transmission. This is e.g. B. the case with full duplex connections, where there is z. B. may be desired on the transmitter side to make it clear on one channel that the receiving side is ready to accept, or that the final signal has arrived. The service mark is then opposite over the other directional channel to send.

The present invention aims at an arrangement which makes it possible, in the case of a rhythmic Telegraph system, d. H. a system in which the telegraph characters are sent in direct order (e.g. punched tape operation) to transmit a service mark over a channel over which a telegram is transmitted at the same time without disrupting the transmission of this telegram or to delay. The arrangement according to the invention has the feature that on the transmitter side

Means are present to reverse the polarity of a start and / or stop step, and that Means are provided on the receiving side which respond when a start and / or stop step is received, whose polarity is opposite to the normal case.

The invention is explained in more detail with reference to a drawing in which

Fig. Ι schematically an example of a radio duplex connection between two stations A and B,

Fig. 2 shows part of a telegraph transmitter and Fig. 3 shows part of a receiver for demodulating a service mark. In the duplex system according to FIG. 1, a telegram can be transmitted from station A to station B by means of a strip punch 1 where the telegram has been set, a telegraph transmitter 2, a radio transmitter 3, a Funkao receiver 4, a telegraph receiver 5, a voter 6, a receiving distributor 7 and a receiving punch 8 that picks up the telegram. At the same time, independently of the first telegram, a dispatch can be sent from station B to station A by means of the tape punch 9, a punched tape transmitter 10, a radio transmitter 11, a radio receiver 12, a telegraph receiver 13, a selector 14, a reception distributor 15 and a reception punch 16. When a dispatch has to be transmitted from station A to station B , station A sends a call signal to station B, where the channel in question can optionally be transmitted numerically by means of a selector 6 is connected to a free receiving hole 8. As soon as this connection has been established n, the telegraph receiver 5 transmits a signal to the punched tape transmitter 10 of the return channel to indicate that a service signal must be transmitted. Station B constantly transmits signals to station A , ie station B sends out auxiliary signals if no dispatch is to be transmitted. All characters, i.e. both the actual telegraph characters and the auxiliary characters, consist of seven steps, of which the first (start step) and the last (stop step) usually have fixed opposite polarities. The starting step is e.g. B. normally always positive, the stop step negative, regardless of the meaning of the So sign, which is determined by the five remaining steps.

According to the invention, a service signal is sent out by reversing the polarity a start and / or stop step. In the present case, only the case is described that the The polarity of a stop step is reversed, but no further explanation is required that basically the polarity of the start step or both steps can be reversed. The telegraph transmitter can e.g. B. be set up in such a way that the corresponding to the characters to be sent Keyed send contact that is always closed during a start step and during a Stop step is open, from the series connection one that is always closed during a stop step Contact and another contact is bridged, which is closed when an official signal is to be sent out, which is the case when the telegraph transmitter 10 does the aforementioned Receives signal from telegraph receiver S. Instead of a negative stop step, then a positive stop step sent one or more times.

An example of an electronic circuit arrangement for this purpose is shown in FIG.

The telegraph characters to be sent out are set in a punched tape of the punched tape transmitter BZ shown schematically in FIG. 2, which is denoted by ι in FIG. The transmission is controlled by a counting circuit known per se, which contains gas-filled tubes B 12 to B 18. The tubes are each provided with a cathode k, an anode α and an ignition electrode f , such as. B. indicated for the tube B 12. The anodes ο of these tubes are connected to the positive pole of the supply battery BB via a common resistor R27 . The cathodes k are connected via the parallel connection of the resistors R 28, R 29, Ä30 etc. and the capacitors C24, C 25, C 26 etc. to the negative pole of the battery BB and further via a resistor R $ i, R32, Ä33 etc. The ignition electrode of the following tube of the counting circuit is connected, the cathode of the last tube B 18 being coupled to the ignition electrode / the first tube B 12 via a resistor i? 34. The step generator SG sends a positive pulse to the ignition electrode of the tubes B 12 to £ 18 of the counting circuit via the capacitors C 27, C 28, C 29 etc. every 20 ms. In operation, only one tube of the counting circuit is ever conductive; at a certain moment z. B. the tube B 13. As a result of the voltage loss occurring at the resistor R 29, the potential of the ignition electrode of the following tube B 14 is then higher than the ignition electrode of the other tubes, so that the following pulse of the step generator ignites the tube B 14, the tube B13 goes out due to the common resistance R27 in the anode circuit. In this way, a subsequent tube of the counting circuit is ignited every 20 ms.

The various tubes control the transmission of the various steps of a telegraph signal.

The first tube B 12 controls the first step, the starting step, which always has positive polarity, the tubes B 13 to BiJ control the following five alphabet steps, which form the actual telegraphic symbol and whose polarity depends on whether there is a hole in the paper tape of the Punched tape encoder BZ is or not; the tao tube B 18 controls the last or stop step of the character; this step normally has negative polarity, which is however inverted into positive when a service signal is to be sent out. The cathode k of the tube B 12 is connected to the point ZP via the rectifier G ι. The Catho-

those of the tubes S13 to B 17 are connected to the punched tape generator BZ via rectifiers G 2 to G 6 and are connected to the point ZP there by contacts, not shown, which are controlled by scanning pins testing the punched tape. When the tube B 12 is conductive, the point ZP has a relatively high potential corresponding to the positive polarity that the starting step should have. If the tube B 13 is conductive, the polarity of the point ZP is relatively high if the corresponding contact of the tape transmitter BZ is closed, ie if a positive step is sent, or relatively low if this contact is open; in this case the step is negative. Likewise, the following steps of the telegraph character from the tubes B 13 to Biy are controlled in accordance with the character punched in the tape. As long as the tube B 18 is conductive, the point ZP has a relatively low one

ao potential corresponding to the negative polarity that the stop step must normally have. When the tube B 18 becomes conductive, the cathode dieser.Röhre transmits via line TL to the punched tape encoder BZ a pulse, which in this the paper tape is further transported to a Zeichenlochung in a manner not shown, and the scanner pins to scan the next character. The Telegraphierzeichen which appear stepwise in this way at the point ZP. Forwarded existing means of a gas-filled from the tubes 10 B and Bn Kippschaltanordnung to the radio transmitter 3 in Fig ι. The anodes of the tubes B 10 and B 11 are connected to the positive pole of the battery BB via a common resistor R 26. The cathode of the tube B 10 is connected to the negative pole of the battery via a capacitor C 21, the cathode of the tube Bn is also connected to the negative pole of the battery via the parallel connection of the resistor R 25 and the capacitor C 23. The ignition electrode / 1 of the tube Bn and the cathode of the tube B 10 are each connected to the point ZP via a resistor R21 or R22 . The step generator SG feeds the ignition electrodes / or fi of the tubes Bio or Bn via the capacitors C 20 and C 21 a positive output every 20 ms. Impulse to. If at such a moment the point ZP 'has a relatively high potential, e.g. If, for example, the tube B 12 is conductive, a voltage arises between the ignition electrode / 1 und.der cathode k of the tube Bn that this tube becomes conductive. The line RZ transmits a positive step from the cathode of the tube Sn to the radio transmitter. If the point ZP has a relatively low potential during the time period in which the tube B 13 is conductive, the cathode of the tube B 10 will also have a low potential. During the next pulse supplied via the capacitor C 20, a voltage arises between the ignition electrode, which carries a bias voltage from the voltage divider i? 23, R 24 , and the cathode of the tube B 10. this tube ignites. Here, the tube Sn extinguishes due to the common resistance S 26 in the anode circuits. The cathode of the tube Bn now transmits a negative step to the radio transmitter. The tube S10 goes out automatically. If the point ZP had had a relatively high potential while the tube S13 was conductive, the tube Bn would have remained conductive and a positive step would have been transmitted to the radio transmitter. In this way, the toggle switch transmits the telegraphing steps occurring in point ZP to the radio transmitter with a delay of 20 ms. The last or stop step, as already said, usually has a negative potential. This step is fed to the radio transmitter via line RZ during the conduction period of tube S12, since tube B1 1 was extinguished at the end of the time period during which tube B 18 was conductive; during the last-mentioned period of time, the point ZP in any case has a relatively low potential.

If a service signal has to be sent, ie the polarity of the final signal is to be reversed, the contact cd is closed by means not specified, whereby the ignition electrode of the tube S 20 receives a relatively high bias voltage from the voltage divider R40, R41 tube B 20 is connected through resistor R 36 to the positive terminal of battery BB and the cathode via the parallel circuit of the resistor R35 and the capacitor C31 to the negative terminal, the step generator SG performs every 20 ms, the ignition electrode of the tube 20 via B the capacitor C 30 a positive pulse to thereby this tube ignites and thereafter again automatically turns off because the resistance R 36 has a high value. the capacitor C 33 thus transfers each 20 ms to the ignition electrode of the tube B 19 a positive pulse, as long as the Contact cd is closed. This ignition electrode is connected to the cathode of tube B 18 via resistor R 3g , so that the se electrode, as long as the tube B 18 is conductive, has a relatively high bias voltage. Thereafter, the tube B 19 ignites under the influence of the positive pulse supplied via the capacitor C 33, the cathode of the tube Big, which is connected to the ignition electrode f2 of the tube Bn , assuming such a potential that the tube S11 ignites. The tube S19 goes out automatically. Although the tube B 10 also ignites in this case, whereby the tube B 11 would normally be extinguished again, the ignition electrode / 2 of the tube Sn retains a relatively high potential for a sufficiently long time so that the tube S11 does not go out in this case and over the Line RZ supplies the radio transmitter with a positive stop step.

The change in polarity of the stop step is noted by the telegraph receiver 13 of FIG. 1 in station A , after which the telegraph receiver 13 transmits a signal to the telegraph transmitter 2 as a sign that the telegram

can be sent, for example 'at the end of the telegram from station A, a service signal is transmitted by station B as a sign that the final signal sent by station A has been received in station B and recognized as such.

The telegraph receiver 13 contains a circuit arrangement shown in FIG. 3 for synchronization of the recipient in relation to the

start and end of the received character and to note a service mark. The synchronizing arrangement uses the fact that the start and stop steps are usually fixed Have polarity so that the transition from negative polarity to positive polarity when disconnecting a stop step and a start step at the beginning or at the end of the telegraph characters occurs periodically while such a transition occurs in the separation of other steps of the telegraph characters will not be there periodically, provided that at least that the same character is repeated.

The circuit arrangement includes to this end a counting circuit which is set up in a similar manner to the counting circuit of FIG. 2, k with seven gas filled tubes Bi to By, each having a cathode, α an anode and f of an ignition device, such as for the tube B 1 is shown. In the cathode lines of the tubes there are resistors Ri to Ry which are bridged by capacitors Ci to Cy. The ignition electrodes of the tubes B 2 to By are connected to the cathode of the preceding tube of the counting circuit via resistors R 8 to R 13; the ignition electrode

of the tube B 1 is connected to the cathode of the tube B y via the resistor R 14. Only one of these tubes is conductive at a time. In the anode circuits of the tubes there is a common resistor 15, so that when a tube is ignited, the tube that is conducting at that moment is extinguished. A step source IB, not shown, which is synchronized with the telegraphic characters received in a manner not shown in detail, periodically supplies the ignition electrodes of the tubes B 2 to By every 20 ms via the capacitors C 8 to C13 with a positive pulse at times that coincide with the separation between the various steps of the telegraphic signs. In the rest position of the counting circuit, the tube B y is conductive, since the ignition electrode of this tube is connected to the positive terminal of the battery Ba via the resistors R 16 and R15 and thus has a higher bias voltage than the ignition electrodes of the other tubes. The telegraphing steps received are fed to the input terminals IK. It is assumed that the counting circuit is temporarily not synchronized with the received characters. As a result of the differentiating effect of the capacitor C 14, a positive pulse occurs at the control electrode of the tube J51 when there is a transition from a negative to a positive step, and a negative pulse when the transition in the opposite direction occurs. Of these, only the positive impulses can be effective. The tube 51 ignites with the first positive pulse. The counting circuit now counts six pulses under the control of the step generator IB. With the first pulse, which is emitted by the pulse generator after the ignition of the tube B 1, the tube B 2 ignites, because the ignition electrode of this tube is connected to the cathode of the conductive tube B 1 via the resistor R 8 and therefore now has the highest bias voltage. At the same time, the tube B1 goes out. Likewise, tube R 3 ignites with the second pulse, etc. until tube B y has become conductive with the sixth pulse. If, however, positive pulses should again have been fed to the control electrode f of the tube B 1, these remain ineffective, since the tube B y is non-conductive and therefore the ignition electrode of the tube B1 has a relatively low bias voltage. First of all, it is assumed that the first positive pulse supplied to this ignition electrode does not coincide with the beginning of a telegraph character, but z. B. occurred at the end of the third step of this character. The counting circuit has then returned to the starting position at the end of the third step of the next character. If at this moment there were again a transition from negative to positive, then the counting circuit counts down anew six pulses from the pulse generator IB . If this is not the case, however, the counting circuit remains in the rest position until such a transition takes place again. After a short time in this way the counting circuit will go in step with the telegraph characters, and tube B 1 will be ignited at the transition that occurs when the stop and start steps are separated , the ignition electrode of tube B 1 always restarting after seven steps a new pulse is supplied and the counting circuit continues to count without interruption. The input terminal IK is further over the resistor !? 17 connected to the ignition electrode of the tube Bg , in whose anode circuit a winding of the relay Di? is recorded. The ignition electrode of tube B 9 is coupled via the capacitor CiS to the cathode of tube B 8, whose ignition electrode is also supplied with the pulses from the pulse generator IB via the capacitor C 16. The ignition electrode of the tube B 8 is connected to the resistor J? 18 at the cathode of tube B y, so that tube B 8 always ignites at the first impulse from generator IB that follows the conduction of tube B y , in other words normally always at times coinciding with the separation between two telegraph symbols. The cathode circuit of the tube S 8 contains a resistor i? Bridged by the capacitor C 17. 19, which is so large that the tube B 8 goes out again by itself. If a service signal were to arrive, the polarity of the stop step is reversed so that the stop and start steps have the same positive polarity. The capacitor C 14 then does not transmit a positive to the 1 * 5 ignition electrode / tube B1

Separation pulse. It is, however, as already noted, the tube B 8 ignite and capacitor CiS the ignition electrode of the tube B ρ transmit a positive pulse at the beginning of the opening symbol, whereby the tube ignites B 9, since its ignition electrode connected through resistor R 17 the input terminal IK is connected, has a high bias at this moment, since the S top step has been positive. When the tube Bg is ignited, the capacitor C18 of the ignition electrode of the tube B 1 transmits a positive pulse from the cathode of the tube B 9, so that the counting circuit continues to count without interruption.

At the same time, the relay DR is energized as a sign that a service signal has been received, whereby further switching processes not described in detail are initiated. The tube B 9 goes out again by itself, since the cathode resistance R 20 is now bridged by the capacitor C 19 and has a very high value.

Claims (1)

Claim: Circuit arrangement for transmitting a service mark in a rhythmic telegraph system, in which each telegraph character consists of a number of steps, of which the first (start step) and the last (Stop step) normally have fixed, opposite polarities, characterized in that that on the transmitter side means are available to reverse the polarity of a start and / or stop step, and that on the receiver side Means are provided which respond when a start and / or stop step is received, the polarity of which corresponds to the normal case opposite is opposite. 1 sheet of drawings S 60 »580/170 8.56 (609 802 2.57)