DE737381C - Circuit arrangement for telegraph systems, in which the change between character and separation pulses and vice versa is transmitted by changing the phase of a carrier current - Google Patents

Description

GERMAN EMPIRE

ISSUE ON! 2: JULY 1Ö43

REICH PATENT OFFICE

PATENT LETTERING

JVl 737381 CLASS 21a ¹ GROUP 7

I61105

Victor John Terry in New Maiden, Surrey, England,

has been named as the inventor.

Hans-Bodo Willers in Berlin

Circuit arrangement for telegraph systems in which the change between character and separating pulses and vice versa by changing

the phase of a carrier current is transmitted

Patented in the German Reich on April 15, 1938 Patent granted on June 3, 1943

According to § 2 Paragraph 2 of the Ordinance of April 28, 1938, the declaration has been made, that protection should extend to the country of Austria.

The invention relates to telegraph systems in which short disturbances can lead to long-lasting errors or series of errors.

Such disadvantages can e.g. B. with pulse telegraph systems appear. In such a system there is no current for the duration of a character or separation pulse. given over the line, but it is only transmitted then a current pulse, if a change is made from the separator to the character position or vice versa is to thereby the armature of a polarized receiving relay to the correct contact to lay. Since the relay is polarized, it keeps its armature in the position into which he was knocked down. As security against unforeseen anchor movement and to achieve a good

Contact pressure is generally the receiving relay with an additional holding winding equipped. The armature is then in the set position by a local current flowing through the holding winding, whose direction is determined by the anchor position. Becomes a Interfering impulse of sufficient strength from the line is received, it becomes a normal one The signal is simulated, the effect of the holding weight is overcome and the 3 ο laisanker placed on the wrong contact. The anchor is now on the wrong one for so long Maintained contact until another. Character or another interference pulse received that puts the anchor back to the correct contact. If there is only a rare transmission of characters, short-term malfunctions can cause errors that last for many seconds,

yes even be maintained for hours.

Similar difficulties arise when transmitting telegraph characters when changing from the character to the separated position and vice versa, the phase reversal a carrier current that is continuously countered via the line. is used. Kick an interruption or malfunction in such a system, this can result in a Reversal of the phase of the carrier current occur, and thereby also the received characters reversed in phase for an indefinite period of time. • 5 The invention avoids these disadvantages in that when the armature of the receiving relay exceeds a prescribed duration remains in the disconnected position, a control relay responds that the phase position between the received and the locally generated carrier currents changes such that the phases in Be brought into agreement.

The invention is explained in more detail below with reference to the drawings. As an exemplary embodiment a system for carrier flow telegraphy has been chosen, in which the changes between character and separating position are transmitted by reversing the phase of the carrier current.

The received characters are fed to a transformer T ₁ (FIG. 1) and from there reach the grids of two amplifier tubes F ₁ and F ₂ connected in push-pull. The output circuits of these tubes are connected via a transformer T ₂ to the input circuits of two further tubes F ₈ and F ₄ connected in push-pull. Two resistors T ₁ and r ₂ are arranged in the grid circles of the tubes V ₁ and V «in such a way that they are simultaneously connected to the grid circles of the tubes F ₄ and F ₃ , so that when the tubes F ₈ and F _4, as a result of the occurrence of grid current, the grids of the tubes F ₁ and F _{2 are given} a negative bias voltage, which reduces the anode current and thus the gain.

The amplified currents are fed via a transformer T _{3 to} a bridge arrangement consisting of dry rectifiers, whose rectifiers / W ₁ to mr _it are connected to the secondary coils of a toroidal transformer T _{4 as shown in FIG} Oscillator tubes F ₅ and V _{0 is} in communication.

The oscillator is kept in synchronism in that part of the output _{energy of the transformer T 3 is} fed to a dry rectifier bridge RB , which generates twice the frequency and feeds this to the tuned circuit L ₁ , C ₁ . The coil L _{1 of} this circle is coupled to the coils L ₂ and Z.3, which are located in the grid circles of the tubes V ₅ and F ₀ .

The receiving relay A is a differentially wound polarized relay which is connected to the rectifier bridge Wf ₁ to _{-IW 1} as shown in FIG. The carrier stream is received continuously. If the received currents are in phase with the currents of the oscillator, then the rectifier mr ₂ and «» '3 full-wave rectification of the sum of the currents fed to the bridge and the rectifier Wr ₁ and mr ₄ full-wave rectification of the difference between the currents, so that a stronger current flows through the right winding of relay A than through the left winding. If the phase of the symbol currents is reversed, the mode of operation of the rectifier pairs also changes, and the stronger current flows through the left winding ".

The character is transmitted by changing the phase of the carrier current with each change from the character current condition to the separating current condition and vice versa. The normal line condition for the transmission of characters from one teleprinter to another is that of the character stream, the received vibrations being in phase with the locally generated vibrations and the armature of relay A being held at the character contact.

Because the local oscillator is synchronized by a frequency which is equal to twice the signal frequency, the phase of the local oscillator is kept constant even when the phase of the symbol streams changes. The control frequency picked up by the rectifier bridge RB shows only slight temporal reductions in the amplitude when the phase of the oscillation picked up changes according to the characters to be transmitted. Twice the frequency is fed in parallel to the grids of the two oscillator tubes F ₅ and V ₆ , and as long as the natural frequency of the oscillator is approximately equal to half the control frequency, exact synchronization takes place. However, the oscillator can just as easily be synchronized either by the positive peaks of the control current, which coincide with the positive peaks of the output current of the oscillator, or that coincide with ^U 5, the negative peaks of the oscillator output current. The local current can either be in phase or out of phase with the incoming current.

Since a change from drawing status to State of separation and vice versa by a

Phase reversal of the carrier stream is effected, it is found that when the phase is not defined above, it also slightly ^p is possible that the characters are reversed, that is one of the desired polarity have opposite polarity.

To set the phase / relationship between the received characters and the oscillator and in certain desired

ίο way to maintain is an auxiliary relayi? provided that in series with a resistor r _s and a dry rectifier Mi? between the positive pole of the local battery LB- and the line ¹ L is switched on.

A capacitor C _{2 is} parallel to the relay B and the resistor r _s . The rectifier MR is switched on in such a way that in the normal rest position, ie when the armature "of the relay A, as shown, is at the sign contact", a current flows through the auxiliary relay B and charges the capacitor C ₂ . The contacts b of the relay B, which are connected in series with resistors and which are parallel to the rectifiers mr _t and mr ₃ , are open.

If the armature of the receiving relay A

' attaches itself to the isolating contact s , the capacitor C ₂ begins to discharge via the relay B and keeps this relay energized. The relay B is therefore in the attracted state during the transfer of the armature of the relay ^! kept depending on the recorded characters. If, however, as a result of an interruption or break in the _{line ending at the transformer T 1} or as a result of a wrong separator, the relay ^ flips its armature and the latter remains on the isolating contact for more than 2 seconds, for example, the capacitor C ₂ discharges completely, the relay B comes to waste and contacts b are closed. This results in a partial short-circuiting of the rectifiers mr _t and mr _z . The balanced demodulator, which is formed by the rectifiers TfIr ₁ to »r ₄ , is now unbalanced, and the incoming wave is now fed directly to the oscillator V ₅ , F _6. The effect on the oscillator is stronger than that of the normal control current of twice the carrier frequency and causes an immediate synchronization of the oscillator in phase, even if it was previously working in antiphase. The relay A therefore puts its. Armature to the drawing contact, the relay B responds, and the balance of the rectifier bridge is restored. The local oscillator now oscillates in the newly pressed phase.

The rectifier MR allows the capacitor C _{2 to} be charged quickly during the symbol periods and prevents it from discharging too quickly during the separation periods. A significant charge current flows into capacitor C ₂ when after a. Medium-length separators, in turn, a character pulse is received or if, after a separator which is longer than the predetermined length, the arrangement is returned to the normal character state. The sudden load on the battery connected to the sign contacts can be disadvantageous in certain cases, since it results in an undesirable voltage drop on the line. However, this disadvantage can be avoided by an arrangement as shown in FIG. Here, the capacitor C2 is slowly passed through the resistor / ' ₃ and the relay 2? during the separation periods ge load. If the armature of the relay ^ passes from the separating side to the drawing side, the capacitor C »is quickly discharged via a closed circuit - which only contains your rectifier and the drawing contact and does not affect the battery in any way. The delayed dropping of the relay B occurs when, after a longer break period, the capacitor C ₂ is charged to such a voltage that the now reduced charging current can no longer keep the relay B energized.

Other arrangements for determining the phase of the oscillator depending on the mode of operation of the relay B can also be used. It is Z. B. possible to operate a changeover switch through the relay B , which reverses the connections from the oscillator to the transformer T _{4 in} order to also reverse the phase of the supplied current without disturbing the synchronization circuit. The polarity of the battery, which is connected to the contacts of relay A , can also be changed using the changeover switch, so that the functions "" 5 of the symbol and isolating contacts are interchanged after an error has occurred.

The mandatory arrangement is for telegraph codes usable, the so-called quiescent current position and divergent temporal has limited working positions. In this case, the hibernation can be unlimited exist for a long time, but the state of work can never exceed a certain one To persist beyond time.

In the case of the character code used on the usual Morse code lines, the _N transmission of separating current corresponds to the idle state and the transmission of character stream corresponds to the working state. The latter never lasts longer than three time units, if with a time unit the shortest distance between

two characters is set. In the case of the part printer code, which is also the case in the present exemplary embodiment was used, the character stream is transmitted in the idle state, and the separation current is limited in time and never lasts longer than six time units. Even if, in addition to the normal characters, this character code contains special additional characters for calling purposes or the like If special signaling is used, it does not take any longer and have a very specific fixed length. Based on these codes it is therefore permissible · to have an abnormally long time interval of the working state as an error display and by returning the system to the idle state, the duration of the Limit error.

In certain cases, however, the character code is not structured in such a way that the idle and working states can be sharply separated from each other in the aforementioned manner. An example of this is a telex self-access switch. It is assumed that two two-wire circuits are provided, which represent a four-wire connecting line between two offices. The normal state of these circles is the so-called disconnected state. When the system is put into operation, while a connection is being set up in exchange A, character stream from A is transmitted along one of the circles that leads to a second exchange B and is designated as the. ^. B circle. The AB-KsUs is connected to voters of office B , and this is indicated by a stream of characters transmitted from B to A via the other two-wire circuit, the Äd circuit. Dialing pulses corresponding to the isolating current are sent via the circuit AB in order to operate the wobbler connected to this circuit or to set additional dialers to establish the connection. During the duration of the connection, character stream is normally transmitted over the lines AB and BA , and this state is maintained with the exception of the times when characters are transmitted which have separation intervals.

It is assumed that a phase reversal carrier current telegraphy system as described above or a pulse telegraphy system is used for character transmission over the circuits AB and BA and that a glitch causes a reversal in one direction either during a pause or during a call. The following processes then result:

Is z. If, for example, a reversal in the ^ i5 circle from the normal separating position to the character position is made during a break, a selector is assigned at B and a character pulse is sent via the iL4 circle. A voter is also seized for A, since A is normally free, and this transmits a character in the ^ -iss circle. However, as a result of the reversal of the working conditions, a separating pulse is transmitted over the line instead of a character pulse. After a certain delay time, the voter at B is triggered and a separating pulse is transmitted back to A via the 5 ^ i circle, which triggers the voter at A. As a result, the starting position is reached again when the interference pulse arrives, and the whole process is repeated over and over again.

The character code used in this system does not correspond to the above because there is no actual rest position and there are both character and separation intervals longer duration can occur. However, it is to be specified as a condition that on The two circuits must have the same state and differences only last as long may be present than necessary to trigger the connection by a disconnection pulse is. With this prerequisite, the arrangement according to the invention can also Be used assuming a facility that has polarity in both Directions monitored.

In such an arrangement, however, it is useful to use the one caused by the error determine the slow oscillation and determine the direction of transmission by comparing the relative lengths of the character and separation periods, in which the error occurred.

In a study of the string that results from the above-mentioned slow oscillation, it follows that, if the fault is such that the phase is reversed in the direetion from A to B, receives the receiving circuit at A slow changes that are of such a nature that the separation intervals are equal to twice the time it takes for a character to run across the circle from A to B or from B to A (running time for the circle), plus the trigger at B, while the character intervals are equal to Double the running time for the circle plus the shutter release delay at A. At B, however, the receiving circuit receives characters that have a bias towards the separating side, since the character intervals are equal to twice the running time, the separating intervals are equal to twice the running time plus the fall-off delays at A and B.

737881

A correction device for determining the line polarity can be built on the fact that repeated separators, which are only separated from one another by periods corresponding to twice the duration of the circle, give an indication that a fault or an error has occurred and that a reversal is necessary. For this purpose, a relay can be provided with a drop-out delay that responds to a trip symbol, ie a separator that is longer than specified. Such a relay is generally already present in the arrangements connected to the circuits of a Fernschneibseibstaiischlußamt. Furthermore, one or more relays are used to distinguish the interval between such characters. With the arrangement of FIG. 3, it can be determined whether a phase reversal is necessary. The arrangements at one end, for example the office B _3, which are used for transmission in the opposite direction, are shown there. Corresponding orders are also provided for in Office A. The relay X _3, which is provided with a drop-out delay, is in series with a rectifier XR in the transmission branch and is energized when a separator is received and made to drop when a character filled with current is received. Each time its contact ^ ₁ is switched, relay Y, which is also a delay relay, is energized and remains in this state for a quarter or a third of a second. A relay Z is connected to the receiving circuit and is biased by the current received via circuit AB. The relay X is energized by an extended separator sent from B , ie during the normal idle state of the circuit, while the relay Y is not energized. When a series of slow changes from character to disconnect is sent from B , relay X is alternately energized and deenergized, and relay Y is kept energized. When a series of slow changes from separating to character status is sent on after the exchange, the relay Z is energized via its left winding. If these changes have such a form that the separation intervals predominate, then the current in the right winding, which is closed via the contact y, predominates the current in the left winding, and the relay Z drops out. If, on the other hand, there is a preference for the character intervals, the relay Z remains energized. The relay Z can thus take over the functions of the relay B described with reference to FIG.

The arrangement described above can also be used to eliminate errors which occur in the unlikely event of simultaneous current reversal on the circuits operating in different directions. In this case, a separator is transmitted from the ^ 4 side of the circles. As a result of the reversal, this is received as a character pulse on the 5-side, so that the voters are seized. The resulting character, which is sent from B , is recorded at A as a separating pulse as a result of the error which has occurred and which causes a reversal. The end of the circle therefore sends and receives a separator and appears free. However, it does not work properly because if a voter at A occupies the circuit and as a result sends a reversal to the character page, this character is received as a separator at B as a result of the disturbance. This triggers every seized voter at B , but only after the usual delay time, and the fact that a character is not immediately sent back to A results in a setting there that corresponds to a character that indicates that all connections at B are busy . As a result, a separator is immediately transmitted from A to B , which is received at B as a character impulse, so that at B the voters are still held. In telex self-access systems, means are already provided which give an alarm if voters remain set for more than a certain period of time without telegraph characters or dialing pulses being transmitted. In response to this alarm, the voters are triggered manually by an operator after the person concerned has made sure that no participants are connected to the circuit. In order to eliminate the error which occurs simultaneously on both line circuits i ° 5 due to an undesired reversal, it is only necessary to ensure that the operator who triggers the selector manually actuates a switch which is triggered by one of the above-described • Means brings about a renewed reversal in a ^{divergence direction.} This means that there is only one error in one traffic direction, and this is eliminated by the aforementioned means.

The the aforementioned method for loading ^1X 5 OTING of reverse faults underlying principle is based on the distinction between working conditions, which are to be considered on the basis of a specific character codes as abnormal, wherein the error correction in response to the occurrence of such abnormal conditions is carried out.

If the code to be used is not structured in such a way that the detection of reversal errors is easily possible, the character code can be changed on the parts g of the line on which reversal errors can occur, using a character code which enables simple detection of the Mistakes allowed. Thus, in self-connecting systems of the type mentioned above, the characters on the carrier circuits working with phase reversal can be converted into a character code that corresponds to the normal teleprinter code, in which it is only necessary to determine the abnormal length of a state that is normally only of limited duration allowed.

This idea and its practical realization are shown below in Figs. 4a, 4b, 4c, 5 and 6 explained in more detail. Fig. 4a shows schematically the characters which occur in a telex self-access system. The normal hibernation for the Separator is marked with I, the call state that corresponds to the character impulse, with 2. This is followed by the characters of the message or the dialing pulses 3, which are sent by short separation intervals are interrupted, followed by a pause on the drawing side 4, which in turn can be followed by characters in the opposite direction. Finally, a trigger follows at 5, which continues to continue at 6 as an idle state.

Fig. 4b shows schematically in which way these characters can be reshaped to be tim usable for carrier stream telegraphy. The normal state is the character status 7. A callsign appears as a short separating pulse S, which is then followed by the character status 9. The dial or signal pulses at 10 appear as short separating intervals in the character stream. The trip sign is denoted by 12 and represents a separator, which, however, is followed by the idle sign in the form of a quiescent current at 13.

An arrangement for converting these characters is shown in FIG. SL represents the transmission branch of the direct current circuit in which the characters of FIG. 4a occur. In parallel, there is a delay relay P in series with a rectifier PR in such a way that the relay responds to a character pulse, for example of negative polarity. In parallel with the relay P there is a capacitor C ₄ in series with a resistor, such that the response of the relay to a character pulse is delayed by 20 m / s and that it drops after 400 m / s as a result of a separator. Normally, if there is a separator on the line SL, the relay P is de-energized, and the TrcnnpH-ntial of the line SL is via the. Contact p is fed to the modulator M (JD , which causes the transmission of the carrier currents via the line VFL.

If the normal separating current on the line SL is changed to a character current, the change in current via the modulator MOD causes a phase change in the carrier current sent over the line VFL in order to generate the separating character 8. After 20 m / s relay P responds and reverses the direction of the character stream from the line SL through the modulator MOD at the contact ρ , so that a further current reversal takes place via the line VFL , which now results in the character status 9. The separating pulses 3 on the line SL are fed to the modulator MOD via the normally open contact p , so that the changes between separating and character currents pass unchanged, as indicated at 10, via the line. The character status 4 is also passed on unchanged as character status 11. This is followed by the separation state 5, which is transmitted via the modulator MOD as separation interval 12. After 400 m / s a time which exceeds the normal duration of the trip signal 5 ", the relay P comes to waste, turns its armature and thus also reverses the direction of the separating current flowing through the modulator MOD, so that it now on the line VFL restores the character state 13. In parallel with the contact / 'there is a resistor r ₄ which sends a current through the modulator MOD during the changeover time of the contact in order to maintain the current state. "> °

The circuit shown in FIG. 6 can be used on the receiving side in order to convert the characters according to FIG. 4b into the characters in FIG. 4c, which are fed to the further connection circuits. The relay Q is connected to the line L , via which the characters according to FIG. 4b are sent from the transmitter relay A of FIG. Relay Q is between the line L, a rectifier Q ₃ , which only lets character current through, and earth. The relay Q responds quickly to the character current, but drops ajb with a delay in the case of the isolating current due to the parallel connection of the capacitor C _5. During the character interval 7, relay O is energized and keeps its contact q open. The relay T, however, is kept energized by the separating battery 30 via its left winding, the closing contact Z ₁ and the sign potential on the line L. In the office facility, separating current is supplied via the line EL from the separating battery 31 via the contact c _ä.

sends. This results in the Treonn state 14 according to FIG. 4 c. As soon as the separating pulse S is received, relay T drops out immediately, since the separating voltage is opposite to the voltage of the battery 30. The line EL is connected to the line L via the contact U , so that the disconnected state continues to be sent via the line EL , to be precise during the time interval 15, which corresponds to the length of the interval 8. If the character status 9 is now transmitted via the line L , this is passed on as the character status 16 to the line EL . The transmission of the character and separation status 10, 11 into the line EL also takes place in the same way, as is indicated at 17 and 18 in FIG. 4c. During this time the relay Q remains energized and keeps its contact q open. During the long separator 12, the relay Q ab is energized, and the relay T responds via its - right winding and the contact q , so that the separating battery 31 is now applied again to the line EL via the contact t ₂ . If now the character state 13 occurs on the line !, and if relay O responds again, relay T is with the line · L above his. Contact t _x connected and remains energized, so that the separating battery 31 on the line- EL maintains the separating condition · 19. It can thus be seen that the characters according to FIG. 4, a of the line EL, which lead to the teleprinter circuits of another office, as characters according to FIG. 4c, which are only shown by the characters of FIG. 4a by the slight delay at 15 when changing from the separated state 14 to the character state 16 in relation to the change from the separated state 1 to the character state 2. The characters of Fig. 4b present on the trunk are subject to the same restrictions as the normal teletype code, and therefore the arrangements of Figs. 1 and 2 can be used to restore normal conditions after successive faults due to disturbances Series of reversals or such reversal series in which the one working condition does not predominate have occurred.

Claims (4)

Patent claims: i. Circuit arrangement for telegraph systems in which the change between Character and separating pulses and vice versa is transmitted by changing the phase of a carrier current, with a polarized receiving relay responds in one direction or the other to whether the received and the locally generated carrier currents are in phase or opposite phase, characterized in that that if the armature of the receiving relay remains in the disconnected position for a prescribed period, a control relay responds that the phase position between the received and the locally generated carrier currents changes so that the phases are brought into correspondence. 2. Circuit arrangement according to claim ι, characterized in that the received carrier currents are fed to a balanced bridge, which the locally generated currents with the help of a Toroid'spuk, which has a secondary winding in each bridge arm, are pressed, and that the control relay off the bridge brings the equilibrium so that the received currents act directly on a local oscillator (V ₅ , V ₀ ) and influence its phase. 3. Circuit arrangement according to claim i, in particular for telex • switching systems, in which the direct current signals emanating from an exchange are to be transmitted to the remote Office can be implemented in a phase change of a continuously transmitted carrier stream, characterized by a relay (Z, Fig. 3), which is de-energized or energized, to the arrangement in the normal state to bring back, if character reversals are made from the office in a time, in the omkehrzeichen, the separation of which predominates, received at the office will. 4. Circuit arrangement according to ■ claim i, in particular for telex switching systems, in which the direct current characters emanating from an office are converted into a phase change of a continuously transmitted carrier stream before transmission to the remote office, characterized in that the direct current characters are converted into a character code before transmission to the remote office in which the continuation of the separation state is abnormal beyond a certain time, and that switching means (relay B, Fig. 1) respond to this abnormal length of the separator. 1 sheet of drawings