DE962714C - Arrangement for the correct phase classification of telegraphic characters in a pulse grid - Google Patents

Description

ISSUED APRIL 25, 1957

vS " 42917 V III aj 21a ¹

in a pulse grid

The invention relates to an arrangement for the correct phase classification of telegraphic characters, especially telex characters, in a pulse grid. One such task is, for example given when over one line in several channels according to the so-called multiplex method several messages, preferably telegraph characters, transmitted by means of pulse modulation should be. In this process, as is well known, the individual characters with the help of a Pulse grid nested and in the receiver again with the help of mechanical or electrical means distributed to the individual subscriber lines. To disruptions as much as possible To avoid this, care must be taken to ensure that the pulse scanning a character element in each case in no case to the time of the turnaround, d. H. the transition from a drawing element to the next, falls, because in this case the polarity of the character element to be transmitted in the receiver could no longer be determined. It is therefore necessary to include the individual drawing elements in the Arrange the pulse grid in such a way that the individual sampling pulses definitely do not correspond to a change in time fall.

With the classification in a pulse grid, the drawing elements are rectified at the same time tied together. For this reason, the phase folder also fulfills the task of an equalizer and can therefore also be used as such.

It is known to construct the equalizer so that the first envelope of the first character element

of a telex character, i.e. the start-up step, a counting device controlled by a pulse raster is started, which counting device after a very specific time, preferably after the Half the duration of the character element - for example at the usual telegraph speed from 50 Bd to 10 ms — a scanner triggers, whereby then from the response, the scanning device to the forwarding the characters Relay automatically until the next sampling time, which is exactly after the prescribed one Character element length takes place, is held in the addressed position. This relay gives thus rectified telegraphic characters, d. H. Telegraphic characters, whose drawing elements have exactly the prescribed length, continue. With the well-known Device, the pulses to be counted are first modulated with the incoming characters to be rectified, and the thus modulated Immediately from the beginning of the drawing element, pulses are applied to the transmitter relay, the to pass on the corrected characters, controlling flip-flop. At the sampling time, this becomes Toggle circuit bridging rectifier is controlled in the blocked state, so that then the toggle relay is controlled accordingly by the pulses modulated by the characters themselves. Through this additional Modulation of the character elements is given the risk of the characters appearing on arrival are already more or less mutilated anyway, become even more distorted. In addition, the modulator to be provided means an additional effort.

The arrangement to which the invention relates is directed towards phasing of telegraphic characters consisting of character elements of the same length and always in the same number, in particular telex characters, in a pulse grid and / or to rectify these characters ■ 40 at least one counting device is also provided, which causes the individual characters to be scanned in their middle, with a counting device is also provided for counting the character elements belonging to a character is. The arrangement according to the invention is more similar in contrast to known arrangements Kind characterized in that both counting devices and one to be ordered or equalized Toggle switching of a signal to a transmitting relay by a receiving relay controlled arrangement prepared for scanning at a specified time and that this is determined by the first counting device (scanning counter) Sampling time ■ which has already been prepared according to the polarity of the incoming character Toggle circuit and the second counter (monitoring counter) by a single Pulse triggered.

The operation and the advantages of the arrangement according to the invention are based on the In the drawing in principle illustrated embodiment illustrated in detail.

Fig. Ι shows a circuit diagram and

FIG. 2 shows a state plan (time diagram) for the individual discharge vessels contained in FIG. 1.

In the embodiment according to FIG. 1, the receiving relay E is arranged to reproduce the characters arriving via the line αΐ, & ι, the armature e of which is the ignition electrode of one of the discharge vessels Röi and Rö2, e.g. B. gas-filled cold cathode tube ^ each applies voltage. In the idle state, i.e. when separating current flows on the line, the armature e is in the separating position shown and the tube Röi carries current. These two tubes carry electricity in the rhythm of the incoming telegraph signals. In this case, the turnover time of the relay armature e, which would narrow the equalization leeway, is eliminated. The anodes of these tubes are connected to the positive terminal + AB of the anode battery via the resistor Wx , and the cathode of the tube Ro 1 is connected to the resistor W2. connected to the grounded, negative electrode - AB of this battery. The resistor W2 is bridged by the capacitor C 2 and in this state - since a very specific voltage drops across the resistor W2 - charged accordingly. At this point in time, the tube Ro 10 also burns, the anode current of which excites the transmitter relay S in such a way that the outgoing line α 2, & 2 also has a current state. The tube Ro 10 receives anode voltage via the transmitter relay 6 ″, the resistor W 3 and the line L3. In addition, this tube is connected to the negative electrode - AB of the battery on the cathode side via the resistor W4 bridged by a capacitor C 4 The circuit also contains, as a scanning counter, a counting chain consisting of the tubes RoJ ₁ to i? Ö8, which is switched on by a 300 Hz pulse fed in via the line L10. The counting chain itself is operated in a ring circuit Target duration of a telegraphy step (20 ms) should be completed, from six elements.

In addition to the two tubes Rö 1 and Rö'io mentioned separately above, the tubes Röi8 and Rö'19 also carry current in the idle state. This state of the tubes can also be seen from the state diagram according to FIG. 2, namely the range which is above the time abscissa before time i ₀ applies.

In the circuit of the receiving relay E , a start-up relay A with a winding I is also arranged. The second winding II of this relay is arranged in the anode circuit of the first counter 10. The two excitation windings are coordinated in such a way that although winding I arranged in the circuit of receiving relay E can trigger the relay, as soon as winding II located in the anode circuit of the counter carries current, the first-mentioned winding has no effect on the work of the relay remains.

If a character (startup script) is received at time t ₀ , relay A and receiving relay E respond. As a result, the armature e of the receiving relay E is first turned over, so that the tube egg? Ö2 is now ignited. Because of the voltage drop occurring across the resistor Wi , the tube Röi is extinguished. The tube Rö 2 is on the cathode side via a resistor W $, which is formed by a capacitor C 5

ίο is bridged, connected to the negative electrode - AB of the battery. As soon as the tube RÖ2 carries current, it prepares the tube Rö ι1 via the resistors W6 and W ¹ J , ie it applies a voltage to the ignition electrode of this tube, which

¹ S is not sufficient to ignite this tube, but - as will be explained in the following - it enables this tube to be ignited when a pulse arrives. The circuit controlling the transmission relay 5 ¹ , in which the from the

so tubes Rö io and Ron existing flip-flop is arranged, so it is prepared according to the polarity of the incoming character.

In addition to relay E , as already mentioned, start-up relay A has also responded and switched the two contacts al and all controlled by the armature of this relay. This ignites the tube Röj, since the capacitor C 6 charged with positive potential is discharged via the resistors W% and Wg via the ignition electrode of this tube. The second winding II of the start-up relay is arranged in the anode circuit of this tube, as is the resistor Wio, which is also located in the anode circuit of the tube Rö ig . The tube Rö 19 must go out because of the increasing voltage drop across this resistor Wio .

By means of the capacitor C11 arranged in the cathode circuit of the tube tube 3 and bridged by a resistor Wi 1, the tube R04 is prepared for ignition via the resistors W12 and W \ Z after the tube tube has been ignited 2) as soon as a voltage pulse is supplied to the ignition electrode via the line Lio and the capacitor C 13.

As soon as the tube R04 has ignited, the tube egg? Ö3 goes out and the tube egg? O'5 is prepared and ignites with the subsequent pulse which is fed to this tube via the capacitor C 14 and the resistor W 14. Since a 300 Hz pulse is fed to this first counting chain via the line Lio, the counting device switches on every 3.33 ms, so that one cycle with six tubes makes up exactly 20 ms, i.e. the usual length of a telex character.

In order to coincide the processes explained, reference is again made to the timing diagram in FIG referenced. Line 1 shows over the common time abscissa 19 the line Lio (Fig. 1) incoming 300 Hz coil. Line 2 indicates

Hand of the state of the tubes Rö ι and Rö 2 the shape of the arriving character to be rectified or classified. As long as the tube Rö 1 is burning, there is a separating current on the incoming line, and if this separating current changes to a symbol current at time t ₀ , the tube egg? Ö2 ignites and the tube Röi is extinguished. At the same point in time t ₀ , as already explained, the tube egg? Ö'3 ignites by switching the contact al. As a result, the tube Rö 19 goes out. In addition, when the contact is turned over, all of the tube Rö 12 ignites and the tube Rö 18 goes out. After the tubes mentioned have ignited, tubes R04, R05 and subsequently Rö 6, R07 and Rö8r ignite one after the other.

In the cathode circuit of the tube R05, as in the case of the other tubes, there is also a resistor capacitor element which, as soon as the tube R05 burns, raises the cathode potential of this tube. This will 'once through resistors PFi 5 and W16 the Röhrei? OE6 prepared 8 "and simultaneously through the resistors 7 and Wi WI8 the tube Roeg. At the next pulse (see FIG. 2) the tube 6 and at the same time the tube 9 is ignited, which passes on a pulse through the condensers Ci9 and C 20 via the line Li, so that the tube Ron and the tube Turn tube i? Öi3 ignited. Because of the voltage drop across the resistor W21, the tube Rö 12 goes out at this point in time. In addition, when the tube Rö 11 is ignited, the transmitter relay 5 ^{1 is} switched, the tube Rö 10 is extinguished and the signal is sent to the transmission line. The counter 10 then continues to run until the tube 8 has ignited, which in turn prepares the tube R03 again via the line L12.

It is now assumed that after the start-up step, as can be seen from line 2 of the circuit diagram, an isolating current step is to follow. The receiving relay E with its contact e in turn puts voltage on the tube Rö ι , iso that this tube is ignited and the tube Rö 10, which has meanwhile gone out, is prepared via the resistors ^ 22 and W23. The start-up relay A is held within the counting device 10 by its winding II, although separating current is now flowing on the line. Now, this counter proceeds to Röhrei? "5 uad outputs a pulse to the tube Roeg, which in turn passes a pulse to the tube Ro 14 via the capacitor C 24, and in this case via the capacitor C 25 to the tube Ro 10 so that the tilting device and thus the transmission relay S changes over and thus also gives the separating current to the outgoing line α 2, b 2 again. As can also be seen from the diagram, this changeover takes place exactly after 20 ms, since the changeover is only triggered by one of the pulses of the 300 Hz raster, precisely corresponding to the number of tubes in the counter after the sixth Impulse that originally controlled the use of the first character. Now, as described for the first character element, the second, third, fourth and fifth character elements of the teletype character and the locking step are equalized and

forwarded. After the fourth character element has been forwarded, i.e. at the beginning of the fifth character element, the tube Rö 18 is ignited in the same way as the tubes R013, RÖ14, Röi $ to Röiy were switched on. This tube prepares the tube Rö 19, which is ignited at the next pulse coming from the tube Rö 9, thereby bringing the counting device 10 to a standstill. As soon as this counting device is switched off, the relay A drops out, and the entire arrangement resumes its original state, so that when a new character arrives, the described process can be repeated according to the nature of the individual character elements. The tube Rö 18 also prepares, as already mentioned, via the resistor W24. the tube Rö 19 also via the line 11, the tube R012 for ignition. In the normal process, at this point in time, since the blocking step is on the anao coming line, the tube Rö 1 burns, so that the preparatory voltage for the tube Rö 12 can flow through the resistor 1 ¥ 2ζ, the line 12 and the resistor Ws . Only when the tube Rom should burn 2, this voltage is present at the ignition electrode of the tube Rom 2, so that the next of the Röhrei? Ö "9 next pulse this. Tube and not the tube Rom ignites 19th This is also the counting chain This measure ensures that if a continuous signal stream is received on the input side, it can also be transmitted via the continuous signal stream output exceeds, comes to a standstill at a certain moment. ~ 'The whole normal scanning process \ vi <-d thus determined by the position of the start-up step within the pulse pattern, -yn at the individual times of the change of the characters or the transmission relay only be determined by the ^ ul'sraster. The transmitter relay arbeii et, w ^; *> line 18 in Fig. 2 shows, very p precise, and the individual characters are exactly the same length and arranged in the pulse grid. If these are scanned by the transmission relay for further transmission now, this may vary depending on the method used for classification or equalization pulse patterns are very simple and very precisely made to a time at which no envelope of the mark ^r 'erf gt. When using the described arrangement as a pure. Phase folder can also be dispensed with entirely on the transmitter relay; the equalized telegraphic characters can in this case also be taken directly from one of the cathode resistors of one of the tubes Rö 10 or i? ön or scanned by a synchronous distribution system.

The execution of the arrangement according to the invention is not limited to the embodiment described, but there are the various the most varied modifications possible. For example, a pulse grid of 6g already results other frequency a differently worked counter, which accordingly consists of more or fewer individual tubes would have to be built up, whereby this would be the case when using the arrangement as an equalizer can be advantageous to choose a higher pulse rate. However, this will also the effort is correspondingly greater.

In addition, it is by no means necessary to implement the invention, the counting device build up from individual tubes, but the well-known decade counter tubes can also be used immediately used, which accordingly when used as the first counting device (scanning counter) would have to be switched in the ring, that is, in such a way that after the ignition of the last discharge path the first discharge path is being prepared again. Besides, it goes without saying easily conceivable, one or the other of the controlled by the receiving relay or the tubes controlling the transmitter relay by a mechanical switch, e.g. B. another relay, to replace. Conversely, one or the other relay can of course be implemented through at least one gas discharge vessel be replaced. However, the use of relays at the input and output has the advantage of that the individual circuits are galvanically separated from each other.

Finally, it should be pointed out that instead of cold cathode tubes, cathode-heated electron tubes or gastriodes with a heated cathode can be used if this should be necessary occasionally in a special case. Instead of the tube Rög used in the exemplary embodiment , the pulse to be generated for scanning and advancing the second counter can also be taken directly from tube R05 , for example by providing a differentiating transformer in the anode circuit of this tube, which is equipped with a rectifier and ¹ Resistance is loaded, so that when the tube is deleted, a short pulse is emitted. The tube egg? Ö'9 can then be omitted entirely.

In the description of the example, nothing is said about the installation of a so-called short start lock. In a practical embodiment of the arrangement according to the invention, such a short start lock will be provided. This can, for example, be in series with the. Receiving relays are switched and act directly on the described arrangement, z. B. by the fact that the tubes Rö 18 and Rö 19 are ignited prematurely, which has a reset of the entire device; In this case, the transmitter relay would necessarily have to be brought into the position corresponding to the position of the receiver relay, if it had already responded. It does not need to be emphasized in detail that the pulses possibly to be provided for scanning must have a rigid frequency relationship to the counting pulses, since

otherwise the desired advantage that the sampling pulse should not fall on a change in time, in Question would be asked.

Claims (8)

PATENT CLAIMS: 1. Arrangement for correct classification into a pulse raster and / or to rectify drawing elements of the same length always in the same number of existing telegraphic characters, in particular telex characters, by means of Center sampling of the individual character elements, the sampling times for the Character elements of each telegraphic character through the use of its first character element With the help of a »controlled by the raster pulse, possibly consisting of several counting chains Counting means (scan counter) are set and the number of times of the scan counter for each part ^ graphic characters to be output sampling pulses limited by a further counter is, characterized in that both counting devices and one to be ordered or characters to be rectified to a transmitter relay relayed by a flip-flop by a receiving relay controlled arrangement out for the scanning in the specified Time to be prepared and that determined at this by the scanning counter Sampling time which has already been prepared according to the polarity of the incoming character Toggle circuit and the second counter (monitoring counter) through a single pulse can be triggered. 2. Arrangement according to claim i, characterized in that that the incoming characters are fed to both the receiving relay and another relay whose Armature controls the contacts assigned to this relay so that the two counters start up (start-up relay), and that further by means controlled by the contacts of the receiving relay, those influencing the sending relay Toggle switch is prepared for switching. 3. Arrangement according to claim 2, characterized in that a second winding of the Starting relay is arranged in the circuit of the first counter, such that during the running of this counter this relay cannot drop. 4. Arrangement according to claim 2 and 3, characterized in that as a function of the contact position of the receiving relay one of two discharge tubes, preferably cathode tubes, is made energized and that depending on the condition of these tubes one or the other of the tilting tubes controlling the transmitter relay is prepared for ignition and applied to a voltage that does not yet affect the state of these tilting tubes will. 5. Arrangement according to claim 1 to 4, characterized by one of individual tubes built-up counting chain connected to a ring as a sampling pulse counter. 6. Arrangement according to claim 5, characterized in that the scanning pulse counting device is assigned a special discharge tube (Rög) which is always made conductive with the correct pulse when the counting chain has passed up to a certain level, and which in turn provides the scanning pulse for the transmitter laie controlling flip-flop and the pulse for advancing the second counter (monitoring counter) delivers. 7. Arrangement according to claim 1 to 6, characterized by two independently operated discharge tubes (i? Öi8, RÖ19) which are coupled to both counting devices in such a way that after passing through the second counting device, the first counting device operated in a ring circuit is brought to a standstill . 8. Arrangement according to claim 7, characterized in that each one of the two discharge tubes on the anode side in a manner known per se with one of the counting devices is coupled so that either the counter or the associated tube current can lead. 1 sheet of drawings © «9 706/157 10.55 (609 865 4. 57)