DE738061C - Circuit arrangement for alternating current telegraphy in which the separating and character current steps are transmitted as alternating current trains of the same frequency but different phase positions - Google Patents

Description

Circuit arrangement for alternating current telegraphy, in which the isolating and character stream steps as alternating current trains of the same frequency but different Phase position are transmitted To the transmission of telegraphic impulses, which are composed of separator and character stream steps, it is known to use the separator and symbol stream steps as alternating current lines of the same frequency but opposite Phase to be transmitted (phase jump alternating current telegraphy). The one required for demodulation Auxiliary frequency is obtained in the known method at the receiving location by a Part of the audio frequency arriving with changing phase with the help of the in the receiver generated double current is again in phase, polarized. As more phase sensitive Indicator at the receiver a Rinb nodulator is used, which is in phase AC voltage on two pairs of terminals on the third pair of terminals a DC voltage from Z. B. positive direction, with the opposite phase, however, a DC voltage negative direction. One disadvantage of such receiving devices is therein to see that the recipient has the separator and character side. des- receiving relay only can be clearly differentiated after prior agreement with the sender. This communication can consist, for example, in the fact that the sender prior to the transmission the message is given a separation current for a longer period of time. But now occurs during of the telegraph company on a short-term disturbance, z. B. a line break, or if there is no voltage at the receiver or at an intermediate amplifier, see above is the ability to differentiate between the separator and the character side on the recipient lost. Such mistakes are made in practical telex typing noticeable by swapping the character stream steps with the separating current steps, and wrong characters are printed at the receiver _ The present invention relates to a monitoring device for such phase shift AC telegraphy systems, which makes it possible to lose the correct phase assignment one make the appropriate correction.

It is already a circuit arrangement for the phase jump alternating current telegraphy become known, in the monitoring devices are provided, which at a z. B. after a line interruption @ made wrong phase assignment the correct one Restore the phase position. In the known method, the criterion for a wrong phase position a character stream with a duration that is greater than i q.o ms, used. In the known circuit there is a delay relay via a rectifier switched to the contact circuit of the receiving relay. The armature of the receiving relay remains longer than iq.oms are at the sign contact, the first mentioned will be delayed Relay de-excites and closes two bridge arms of a ring modulator with its contacts in short, whereby the correct phase position is restored.

The well-known reverse polarity method to restore the lost Phasing cannot be found in the conventional telex switching systems apply, since the criterion used in the known reverse polarity switching, namely to use the permanent position of the receiving relay armature for phase correction, in telex technology is already occupied. By the permanent position of the receiving relay armature that is, the final signaling is used in the common telex switching circuits caused.

In contrast, the present invention uses when the phase assignment has been lost a triggering criterion for the reverse polarity, which is used in the common Yernic writing switching systems are used Karin.

According to the invention, the triggering criterion for the monitoring switching means such amplitude changes in the telegraph voltage of the alternating current tel.egraphy channel used in a way that does not occur in normal telegraph traffic.

The invention goes thereby. from the knowledge that a loss the correct phase assignment with the phase jump alternating current tel: egrafie just enter can if the amplitude of the carrier frequency voltage is missing. Preferably come -as a criterion for triggering the phase correction, such amplitude changes into consideration, which have a time course, such as a telegraph filter from which a carrier frequency is switched off. Such a temporal one Course of the carrier frequency amplitude when switching a carrier frequency on and off is known with sufficient accuracy. The settling time of such a filter is determined by the width of its pass band.

Further features of the invention are intended in the following description an embodiment according to the invention are referred to in more detail.

FIG. I shows a circuit arrangement for a transmitting and receiving device for the phase jump alternating current telegraphy with the monitoring means for the correct one Phase assignment.

2 shows the circuit diagram of the monitoring device.

Telegraph characters are sent to offices A and B by means of direct current telegraphy via four-wire double current transmission paths. The lines arriving at and departing from: @. Nitern A and B can be local lines or long-distance lines. An alternating current telegraphy is assumed between the offices A and B , the forward direction of transmission from A to B via one and the rearward direction of transmission from B to A via another telegraphy channel.

The line L; Incoming direct current double current characters are fed to the modulator M via the contact /., 'and the relay I. The carrier frequency is fed to the same modulator 11 via a second pair of terminals from the carrier frequency generator G via the closed contact d., '. An alternating current is generated in the output circuit of the modulator, the phase position of which changes according to the incoming double current symbol. These alternating current trains with different phases are transmitted to office B via the one alternating current telegraphy channel of the transmission path FL, in which there is a receiving device E which converts the transmitted alternating current trains back into direct current symbols. This receiving device F contains a demodulator DJl, an auxiliary modulator HM, two sieves S; and S., and amplifier V; and V .. In the output circuit of the demodulator DM double current characters are created. These direct current signals come from the output of the demodulator Dill via the continuation of the line Li, which can be a long-distance line or a local line.

It is also possible to have a receiving relay in the output circuit of the DemodulatOYSDM to switch and to control the forwarding direction through its contact.

If a line interruption were to take place on the transmission path FL , the correct phase assignment would be lost and incorrect characters could be printed at the receiving location. The monitoring device Ü is provided to avoid this error. The task of the monitoring device consists in establishing a correspondence between the separating or character stream at the transmitter and the stream in the same direction after the receiver. This correcting of the phase allocation is carried out, as will be described later, inter alia with the aid of the auxiliary modulator SHM. The monitoring device Ü contains a rectifier, a monitoring relay A and a monitoring circuit ÜS controlled by its contact, the circuit of which is shown in FIG. The rectifier GI receives its voltage from the amplifier V. of the receiving device E. However, it is entirely possible to derive the voltage required for the rectifier from another point of the receiving circuit E.

The voltage rectified by the rectifier is sent to the monitoring relay A supplied, the. Normally, i. H. if the transmission paths are in order, is constantly addressed while keeping his contact a open.

The level controls provided in the receiving device E make it possible to compensate for voltage fluctuations, so the voltage that the relay A receives is not subject to any fluctuations as a result of level changes. The level control device can be assigned to the amplifiers V, or V @. The time constant of this level control is chosen to be large compared to the settling time of the reception filter S1. This ensures that even the shortest line interruptions are able to trigger the monitoring device. A capacitor C is connected in parallel to the relay A, which causes a relay delay which is equal to or approximately equal to the settling time of the receiving filter S1. Which inevitably accompanies the phase modulation on plitudenmodulation in the frequency range of the receive filter always has a slope that half the settling time of the filter: equivalent. As a result of these amplitude changes, relay A is not influenced by the entire settling time due to its delay and remains at rest.

The reverse transmission direction _ is switched accordingly and provided with corresponding reference numerals.

It is assumed that a line interruption takes place during the operation of the system in the forward transmission direction. When the resulting change in the carrier frequency amplitude, the A relay of the monitoring device U is de-energized, so that the contact a closes. When closing this contact. the monitoring circuit ÜS is activated (see Fig. 2). When the a-contact is closed, the B-relay is made to respond via the circuit + ZB, closed a-contact, B-relay, earth. When the B relay responds, contacts bi and b3 are closed. By closing the contact b, the auxiliary modulator HM (Fig. T) is bridged. When the b3 contact is closed, the F relay is made to respond via the circuit + ZB, contact b3, F relay, earth. As a result, the contact f, (Fig. 1) is turned over, whereby the line L, going out from office B, is switched off and connected to + TB via the contact g,,. A character transmission over the line Lt in the forward direction is prevented. The response of the F relay also opens the contact f2 of the opposite transmission direction L2, as a result of which the modulator M 'can no longer be controlled with direct current in the opposite direction. When the contact f2 is opened, the relay 1 'is also de-energized, which closes its contact i' and thus bridges the transmission modulator M '. The F-relay is delayed, for example by the capacitor C04, so that it is the last to drop out after all the switching processes have been completed. This ensures that lines L1 and L2 are only switched on again after the phase correction process has ended.

When contact b3 is closed, relay interrupter D "E. Receives power from + ZB, closed contact b3, contact cl, D-R2-relay, ei contact, earth. When the D relay responds, contact, dl in the circuit of the E-relay closed and contact d., In the carrier circuit of modulator M ', opened. When the E-relay responds, the e, -contact opens, so that the current for the D-relay is interrupted, whereby the contact dl opens again and the contact d. closes. The consequence of this is that the contact d2 opens and closes in a predetermined rhythm. As a result, the carrier frequency generated by the generator G 'receives an amplitude modulus 'via the contact d2, the closed contact i', via the alternating current telegraphic channel to the receiving device E 'of the office A.

The relay chain consisting of relays G, H, Th (Fig. 2) has the task of receiving and lengthening a single short switching pulse from relay A in order to prevent the transmission of the relatively slow phase correction pulses from: the generator G 'via the' Pendulum contact d. and to ensure that Office A is properly addressed. The relay chain works in the following ways: The relay. G is made to respond via the closed 'b "contact and the capacitor Cl as well as the closed contacts hl, e., Which binds itself via the contact g1 b -Kontaktes at angesprochenem G relay is formed a further circuit for the F-relay; the thermal relay Tlt g3 by the closing of the contact lt through the closed contact caused to respond, the TLR after the heat-up via its contact, the relay H. Circuit: -; - ZB, closed u-contact, relay H, relocated tlt contact, earth. When the H relay is triggered, the changeover contact relocates, the contact h @ closes, creating a holding circuit for the The contacts h3 and lt- open. By opening the h3 contact, the thermal relay is de-energized, so that the tlt contact is closed after its cooling time, whereby the G'-relay is short-circuited and drops out according to Circuit: earth, tlt contact moved back, lal contact moved back, G relay, earth. By de-energizing the relay, the G-Kontaktegl and g are opened and the H relay is de-energized. as a result, if the line interruption has been remedied, the relay chain consisting of relays F, G, H, Th is put out of operation. If during this operating state. the line FL. the opposite direction is undisturbed, then the modulated alternating current trains, which are transmitted from the generator G 'via the pendulum contact to the office A, will cause the relay A' of the monitoring device Ü 'to drop and respond at the rate of the alternating frequency. As a result, the contact a 'also closes and opens, so that the monitoring circuit üS' is activated. The monitoring system ÜS according to FIG. 2 is now to be considered as belonging to office A.

By opening and closing contact a ', the Alternating frequency brought the B 'relay to respond and to drop out, so that its Contact b. ' back and forth between its end contacts in the cycle of the alternating frequency commutes. This causes the relay C 'to respond continuously, since the charging currents of the capacitors C. ' and C; ' one after the other in the same direction over the Relay C flow. When relay C 'responds, changeover contact ci relocated, whereby the relay circuit breaker D 'and E' switched off. will, during the Contact b ,; ' is bridged. This gives the F'-relay power and switches by means of his contacts fi and f. ' the lines L1 and L. from and to the office.

When the contact f "'is opened, the I relay is de-energized, so that the closing contact i bridged the modulator ibl. About the contact d. ' from the generator G an alternating current with constant phase assignment in the direction from office A to office B via the alternating current telegraphic channel bz «-. up to the accepted point of interruption transfer. Once the line interruption has been resolved, forward and flow will flow reverse transmission direction an alternating current with constant phase assignment, whereby the monitored equipment Ü return to their idle state. Simultaneously the correct phase assignment is restored.

Instead of the transmission modulators M and auxiliary modulators H / 11 shown Phase inverters with a characteristic rest position can also be used. For example M or HM modulators can be used that are not controlled from the direct current side Emit a carrier frequency tension of constant phase position. When using such modulators M or HM, the contacts and b1 are superfluous.

Instead of using direct current telegraphy when the F relay is triggered to control operated connection line in the separating layer, can also with longer lasting Line interruption a control of the connection line in the permanent character position with the help of the G-relay via the Kontaktg, so that through this via the connecting line the final character criterion is given.

There is only a two-wire connection between the two offices A and B. in such a way that fier WT channel i in direction: 1-B with one frequency, the IVT channel z is operated in direction B-A with a different (e.g. higher) frequency, then the described monitoring devices can be used equally well.

There is only one message traffic on a two-wire line Direction (e.g. 13. A-B) provided, so the transmission of the correction characters in the opposite direction via an auxiliary channel, the communication channels may be over or under in terms of frequency. This auxiliary channel can be a lesser one Own frequency band than the communication channels, since only the correction symbols lower Telegrafler speed are to be transmitted.

In multi-channel systems on two- and four-wire lines can be used for simplification of The monitoring relay A: and the monitoring device Ü can only be added to one of the channels. The B, Dh and F relays then have a corresponding contact set for each of the channels, .that in the event of a line fault are operated together. .

Claims (1)

PATENT CLAIMS: i. Circuit arrangement for alternating current telegraphy, in which the separating and character current steps are transmitted as alternating current trains of the same frequency but different phase positions (phase jump <alternating current telegraphy) and in which monitoring switching means are provided which, for example, after a line interruption, the correct phase position restore, characterized in that such amplitude changes in the telegraphy voltage of the alternating current telegraphy channel are used as the triggering criterion for the monitoring switching means (Ü), as they do not occur in normal telegraph traffic. z. Circuit arrangement according to Claim i with traffic handling via four-wire lines, characterized in that the monitoring switching means (Ü) are switched in each of the two transmission directions of the four-wire line and, when the triggering criterion for the phase correction is received, influence control means of the opposite transmission direction via their contacts. 3. A circuit arrangement according to claim i and z, characterized in that in the event of a line interruption in one transmission direction, the transmission modulator of the opposite direction is caused to transmit preferably amplitude modulieiter alternating current trains of constant phase assignment, to which the monitoring switching means (Ü ') of the undisturbed transmission direction respond and which in turn transmit the transmission of alternating current trains with constant phase assignment in the disrupted transmission direction until the disruption is rectified. q .. Circuit arrangement according to claims i to 3, characterized in that the monitoring relay (A) of the monitoring device (Ü) contains a monitoring circuit (ÜS) containing a relay breaker (DE) and a relay chain (F, 0, H, Tlt) acting as a catch circuit controls. 5. Circuit arrangement according to claim q., Characterized in that the monitoring relay (A) is de-energized in the event of a line interruption and, via auxiliary switching means (B, D, E) , causes the interception circuit (F, G, H, Tlt) to respond, via their contacts ( 1, g) the retransmission line is switched off by the AC telegraphic receiving device (E) and switched to the permanent separator or permanent character position. 6. Circuit arrangement according to claim i or 5, characterized in that the amplitude monitoring relay (A,) is delayed so that it does not respond to amplitude changes of half the settling time of the receiving filter, however, on Amplitudeänderun gene corresponding to the entire settling time comes to the response. 7. A circuit arrangement for traffic in a monitoring direction according to claim i, characterized in that the correction characters are transmitted via one or more auxiliary channels which are superimposed or superimposed on the message channels. B. A circuit arrangement for multiple systems according to claim i, characterized in that the amplitude monitoring relay is assigned to only one channel or a part of the channels and only one or more monitoring circuits are provided which jointly influence all channels. G. Circuit arrangement according to Claim and 5, characterized in that the F relay is delayed until all the other relays have reached their rest position, taking into account the running time of the channel.