DE1081934B - Circuit arrangement for audio frequency signal receivers in telecommunication systems, in particular telephone systems - Google Patents

Description

The invention relates to circuit arrangements in telecommunications, in particular telephony systems, at which audio frequency current signals for control and monitoring signaling over Trunk lines are used.

In the following, the expression "long-distance line" should be used in the description for reasons of expediency. to be understood in a broad sense to denote any transmission channel which, regardless of whether he uses carrier streams or not, regardless of the remote exchange for the transmission of speech streams in both directions between two long-distance exchanges.

It is already known, an audio frequency signal receiver, which is located in a remote office on one End of a pipeline and which is coupled to the pipeline in the vicinity of this end, to be arranged in such a way that when the recipient is on an actual or replica, from the other At the end of the long-distance line coming audio frequency signal responds, this is a shutdown or interruption or disconnection of the trunk from the trunk at a point which is closer to Office is located as the point at which the receiver is coupled to the long-distance line. Through this parting which can be referred to as "far-end disconnection" because it occurs at the distant end of the Long-distance line takes place at the opposite end from which the signal is transmitted, "Continuing" of the signal beyond the receiver is shortened for a period of time or cut off, which is so short that such "running on" is harmless. Through this separation the length of time during which the receiver over the trunk line is also shortened received signal due to interference currents received from the local office to which the Receiver is connected, can be mutilated. On the other hand, if the receiver streams audio frequency signal receives from his local office (and if this signal streams not for this receiver are intended and therefore represent an error signal for this receiver), the receiver also speaks reacts to these currents and similarly causes the trunk line to be disconnected from the office. Under these circumstances, the splitting of the error signal stream both from the receiver and also disconnected from the trunk line and thus prevents the signal from malfunctioning either this recipient or a recipient on the other The end of the pipeline. The separation that takes place under these circumstances can be called "approaching separation" or "disconnecting the incoming line" as it is caused by signal currents Circuit arrangement

for audio frequency signal receivers

in telecommunications, in particular

Telephone systems

Applicant:

Siemens Edison Swan Limited,
London

Representative: Dipl.-Ing. E. Schubert, patent attorney,
Siegen, Oranienstr. 14th

Claimed priority:
Great Britain 13 March 1956

Bernard Drake, London,
and Frank Allen Stallworthy, Bexleyheath, Kent

(Great Britain),
have been named as inventors

which are received by the local office.

It is common when either a near-end or a far-end cut is to be performed, termination resistors to switch into the circuit arrangement to those subsections in which thus a through transmission path is divided by the severing in a satisfactory manner to end.

In some cases, effects that resemble a near-end and far-end separation are received without any real interruption. The arrangement is instead made so that the Transmission of a signal current to the point in question by means of a short circuit is prevented.

It is also already known an audio frequency signal receiver to be coupled to a long-distance line by means of a directional coupling device (for example a so-called differential transformer), which makes it possible to to transmit signal streams to the receiver which arrive via the trunk line, but which prevents that the recipient receives any streams transmitted from the local office, which the recipient disturb or influence in an unpleasant way. In this latter known circuit arrangement is

009-510/91

3 4

However, the directional effect of the directional markings through which the state or the Coupling device is audibly displayed over the entire duration of a criterion of a connection, Speech connection effective. A near-end to be neglected). The preferred one used

Separation can therefore not occur, since the missing audio frequency is 2280 Hertz.

signal currents which such an interruption are 5 The subscriber line has a Tonfrequenzveranlassen, with the aid of the directional coupling unit signal receiver, which shown as a rectangle E prevented from reaching the receiver. is, of known design and is by means of a This is a disadvantage, since such false signal currents, transformer Ti? 3 on the subscriber line cores in particular simulated signals which are coupled during. Upon receipt of the signal frequency alone a call duration are caused, now io the receiver causes the dropping or releasing in the long-distance line to be able to enter and a normally energized relay XX; However, if the receiver at the other end of the line misactivates speech streams or other streams that cannot. Own signal frequency alone, be received,

With the circuit arrangement according to the invention, a blocking path in the receiver prevents this disadvantage from being circumvented while the already 15 relay XX drops out. The contacts xxl and xx2 of this well-known advantages of using a directional relay are shown in the diagram in their rest states effective coupling device thereby retained. On the subscriber line side (the fact that the directionally effective Kopplungsvor- ken side of the assembled figures) is the direction, for example a fork transmitter, via connections 26 and 27 to the outside on speech wires switching contacts during the speech state of the 20 (line wires) of the long-distance line circuit connected to the Prevention of the forwarding of sen, while on the office side (the right side of the false signals on the following signal receiver shown drawing) the connections 28, 29 and 3G ^; is switched non-directional, for example to the outside in each case on speech wires and test wires, in that the first signal receiver is connected through 25 lines when incorrect signals arrive at a manual switching cabinet or ax, which the subscriber contacts disconnect or otherwise interrupt. is assigned to the management committee. Between the connections

When using the invention, if the sen 26 and 27 and the connections 2 $ and 29 can directionally effective coupling device is formed by a differential over the wires 43, 31, 33, 38 and 35 on the one hand and rentialtransformator, the directional 44 > 32, 34 and 36, on the other hand, a continuity effect is extinguished during the duration of the conversation. a Speechfceistransfarma response signal which has received over the trunk line TR5 .

The wire pairs 39 and 40 are connected to the two signals that the voice connection has been interrupted by operating a signal frequency source (2280 ~) via 35. In addition to the receiver contacts already mentioned, which connections of the transformer relay XX , the control circuit has ten other relay windings change in such a way that the transformer has a relay. CC, a relay BH, a no longer than a differential transformer, which relay DA, a relay-.A4, a relay BR, a relay is effective in the direction of a signal, but now- AX, a relay DP, a relay SX, a Relay DR and more than one forward coupling transformer 40 a relay AK. The five pairs of springs TJ5, Tf 6, T / 7, works, which is switched in a directionally effective manner. T / 8 and T / 9 are springs of a test device,

From the above it can be seen that an invention wherein the pair TJ 7 is normally by a

According to the circuit arrangement the implementation of a bridge arm is bridged. The circuit arrangement

“Far-end separation” at any point in time comprises four non-linear resistance elements

light, during which the long- distance line for a 45 RX 5, RX 6, RX 7 and _{RXS 1} switch is used to provide a

Speech connection is busy, while a »near-end sparking at the contacts xx 1, xx2, and daS

Separation «to be suppressed at any point in time during a treatment.

call duration can be carried out, which is normally the through connection in

Receipt of a supervisory response signal follows. Participant lead rank and office sections at the consortium

The invention is now to be separated on the basis of the axl and ax2 of the relay AX that are clocked at the same time. Of the

for example reproducing drawing detailed office section has a contact aal of the relay AA

will be described, namely those on, while the subscriber line section the

Fig. IA and 1B together a break contacts according to the invention sxl and sx2 of the relay SX and the

Line connection control circuit of the two-wire type normally open contacts ak 2 and ak5 of the relay AK ,

for one end of an inter-office trunk line, 55 The turns of the three-turn

while transformer TRl include in a similar way

Fig. 2 shows a schematic circuit, first and second primary windings (I) and (II) and

which one possible use of the invention is a secondary winding (III). Each primary winding

in the case of a line connection control circuit, it is divided into two unequal sections by a tap

schichticht, which divides for the interconnection of a 60 fung, with the ratio of the turns

four-wire "long-distance line" with a two-wire on the larger and smaller sections of one

Official steering committee is provided. Primary winding is the same as for the two

Reference is first made to FIGS. 1A and 1B, where primary windings. The aforementioned ratio can be these two figures as a single control circuit or expediently 25: 1. The secondary, a single circuit arrangement are to be considered, 65 winding (III) of the transformer TRl is constantly in such a way that Fig. 1B to the right of Fig. 1A is connected to the audio frequency signal receiver. The lay is. The partial connections shown by the circuit of the primary windings (I) and (II) of the subscriber line works so that all necessary signals are dependent on the status of the relay AK via the trunk line in the form of currents of a transformer TR1. As long as the relay AK is transmitted in its normal audio frequency (with the 70 times idle state, these primary winding

Connected to the effect that the transformer TR 1 in connection with a line simulation R 45, C 26 acts as a differential transformer.

The line replication, by taking into account the ratio of the windings on the larger and smaller parts of a primary winding, is intended to balance the long-distance line, seen from the subscriber line. If the aforementioned ratio is 25: 1, the line replica to balance a nominal trunk line impedance equivalent to a resistance of 600 ohms in series with a capacitance of 2 microfarads can be formed by a resistor i? 45, which has a resistance of 15,000 ohms in series with a capacitor C 26 which has a capacitance of 0.08 microfarads. In these connections, the input connection after the audio frequency signal receiver is a directional connection which takes effect to reject audio frequency currents received through the exchange side of the incoming line; however, it can also be a coupling between the trunk line and the receiver. During the time in which the relay AK is in its working state, ie when the contacts ak 1, ak 2 and ak 5 are actuated, the connections of the primary windings (I) and (II) of the transformer TRl are such that the entire first primary winding (I) is a line replica, consisting of a resistor R 46, which is connected in parallel with a capacitance C 27, and the entire second primary winding (II) are connected in series, in the order listed between the subscriber line cores of the through connection, the connection points of this series circuit with the subscriber line cores between the corresponding contacts of the relay SX and the relay AX . The line simulation i? 46, C 27 causes the impedance of this series control circuit, as can be seen from the line wire diagram, to be kept essentially in an ohmic resistance and constant at all frequencies which occur to a significant extent in the conversation. In a typical case, the resistance of this line replica has a resistance of 15,000 ohms and the capacitor a capacitance of 0.018 microfarads. In the case of the last-mentioned connections of the primary windings of the transformer TR1 with three windings, the input connection after the audio frequency signal receiver is a bidirectional connection.

When the subscriber line receives a ringing signal via the trunk line, which is formed by a current pulse of the signaling audio frequency, the relay X of the audio frequency signal receiver, which is normally in the working state, is released for the duration of the pulse. When contact xx 1 is in the rest position , relay BH is actuated in a control circuit via normally closed contacts br 2 and beZ and resistor R 39, and when contact xx 2 is in rest position, the selector relay CC is switched to its windings (I) and (II), which are connected in series, operated. When the relay BH responds, the contact bh 3 closes a working circuit via the break contact br 5 for the pulse relay AA. The last mentioned relay has an associated resistive line replica consisting of a resistor R 40 and a capacitance C 21 to cause it to have small actuation and release delay times which are substantially equal. In this way, response of the relay to short missed pulses is prevented without introducing undue distortion of correct pulses which are repeated by the relay. Upon actuation of the relay CC , the contact cc2 closes a control circuit, which has the pair of springs TI7 to actuate the relay DA on its series-connected windings (I) and (II), and the contact cc4 closes a short circuit, which the Has break contact dr2, via the winding (II) of the relay CC, whereby the relay can be released slowly. After actuation, the relay AA closes a call loop on its contact aa 1 on the office side of the subscriber line, this call loop on contacts dr 6 and cd as long as the relay remains actuated. For the purpose of spark suppression, a resistance line simulation is assigned to the contact aal , which consists of a resistor R 41 and a capacitance C 20. When the relay DA is actuated, the contact da 1 closes a short circuit across the winding (II) of the relay, which is thereby held with a drop-out delay.

When the relay XX assumes its working state after the termination of the pulse of the ringing signal, the contact xxl opens the short circuit which previously existed across the contact bhl over the winding of the relay BR, with the result that the relay BR is in operation occurs, while the relay BH remains held in the control circuit via the resistor R 39 and the contact bhl. Contact xx2 opens the control circuit of relay CC and closes a control circuit to keep relay AA independent of contact br 5. In response to this actuation of the relay BR , the contact brl transmits a switch-on criterion (earth), which is transmitted through the switch cabinet or the incoming lines, which comes into consideration after the test wire to which connection 30 is connected, namely after the lower one Spring of the pair TJ 5, and the contact br 5 closes a hold circuit for the relay DA via the contacts dp 3 and dr3. When the relay CC is released, the opening of the contact ccl causes the ringing loop, which is established by the contact aal , via the winding (III) of the transformer TR5, the rectifiers Mi? -7 and MR 8, resistor i connected in parallel ? 35 and the winding (IV) of the transformer TR 5 (instead of via contact cc 1) is passed through. The quiescent state of the contact cc 5 turns on the winding of the fast switching relay AX, which is connected in series with that of the relay AA , so that the relay AX is actuated, and the relay AA is held via a control circuit which is via the winding the relay AA, bh contact 3, the winding of the relay AX, the normally closed contacts sx 3 and cc5 and extending the working contact xx2. As already mentioned, the through connection is separated into a subscriber line and an office section at the contacts axl and ax2 of the relay AX , the office section (ie the section shown on the right) being connected to a non-inductive resistor R 32 of 600 ohms , while the subscriber line section is connected to a resistor R 42 of also 600 ohms. On actuation of the relay AX as described above, the contacts αχ 1 and ax2 open the connection resistors R 42 and i 32 and thus terminate

the time of the interruption state of the through connection by directly connecting the two sections, whereby z. B, a dialing signal is made possible by which an audible indication of the provision of a subsequent control circuit for receiving dialing pulses is given, which are to be transmitted via the line wires of the subscriber line. The directional connection of the transformer TRl prevents at this point in time that such a signal and all other audio frequency currents are received by the office side of the subscriber line and that the audio frequency signal receiver E comes into action in any way (ie before bringing about or blocking the response response of the receiver). The audio frequency signal receiver can, however, respond freely to a forward signal which is received via the trunk line and formed by at least one relatively long (ie 2 seconds) current pulse of the signal frequency. The directional sensitivity of the transformer Ti? 3 serves to prevent the signal receiver from being influenced by changes (or unsuitable values) in the impedance between the subscriber line cores of the subscriber line, such as from the office side of this subscriber line from the taps of the primary windings (I) and (II) of the three-winding transformer TR 1 can be seen. Such changes can, for. B. occur on actuation of the relay AX . Regarding the transmission through the transformer Ti? 5, the windings (I) and (II) of this transformer are of course directly connected in series, and the windings (III) and (IV) are effectively connected in series through the capacitance.

Dialing digits, which are received over the trunk line as a pulse series of a signal stream with the signaling frequency, are repeated over the ringing loop of the office side of the subscriber line as pauses between the pulses. When a series of pulses with regard to a dialing digit is received, relay XX is released in response to each pulse in this series. If the relay XX is released in response to the first impulse of the train, the contact ⁴ ^ xx2 releases the relays AX and AA and activates the relay CC.

Upon actuation of relay CC , contact cd closes a low resistance loop (which has contact dr6 ) across wires 36 and 38 to prevent distortion in the pulse repetition, contact cc4 closes winding (II) of the relay briefly, and contact cc S switches off relay AX . The relay AX is released before the relay AA , and the contacts ax I and ax2 bring about the separated state of the through connection and thus prevent the audio frequency signal receiver from being influenced by the effect of wave fronts due to the pulses. When the relay AA drops out, the contact repeats the first pulse of the dialing digit, which can be used as an interruption pulse. The relay CC remains activated until the end of the pulse series received, after which it is released or drops out. Its release delay in its shorted winding (II) is sufficient to ensure that it is not released during the intervals between pulse trains. The protective relay BH is held during the series of pulses, with a release delay in its short-circuited winding being sufficient to ensure that it is not released due to the short circuit built up over this winding, which is via normally open contact br 2, normally closed contact xxl, normally open contact br 3 and contact bhl extends during each pulse train. Pulses of the first subsequent row are repeated in the same way as the first. Contact xx2 releases relay AA , and contact aa 1 opens the call loop on the output side. Upon the release of the relay CC at the end of the series, the relay AX is switched in series with the relay AA , and it is actuated again, thereby ending the disconnected state of the through connection. If at the end of a dialing a continuous number of unreachable characters, thereby giving an audible indication of the fact that the partial setup connection cannot be completed, is returned by a control circuit following the subscriber line in question, then these characters are over the subscriber line transmits to the trunk line; but the directional effectiveness of the transformer TR 1 prevents this character from blocking the response response of this receiver to the signal current which is received via the trunk line at this point in time. Thus, when the continuous busy signal is transmitted over the trunk line to its "far end", the audio frequency signal receiver of the incoming subscriber line can respond freely to a forward signal received over the trunk line.

If following the termination of a dialing process a called subscriber or a called operator (remote office clerk) answers the call, the relay DP works on its working winding (I) in response to a reversal of the direct current in the ringing loop, the direct current in this loop on a such reversal towards the terminal 28 via contact aal, winding (III) of the transformer Ti? 5, rectifier Mi? 6, winding (I) of the relay UP, resistor i? 35 and winding (IV) of the transformer Ti? 5 to connection 29 flows. When the relay DP is actuated, the contact d £ 3 opens the control circuit of the relay DA, which is then slowly released, and the contact dpi closes a short circuit via the normally closed contact ak3 through the relay AX, which is then released. The contact dp 5 closes a holding circuit for the relay DP and an operating circuit for the relay SX, the holding circuit for the relay DP via the normally open contact br 5, contact akß and the holding winding (II) of the relay DP and the operating circuit for the Relay SX is composed of the normally open contact br 5, the normally closed contact dr 5, the contact da5, the normally open contact br 4 and the contact cc 3. When the relay SX is actuated, the contacts sx 1 and sx2 transmit signal current to the voice wires of the trunk line, and thus begins the transmission of the first pulse of a response signal, which is formed by a pulse of signal current; followed by repetitive similar pulses when an acknowledgment signal becomes effective and is received through the subscriber line. When the relay AX drops out, the through connection is again disconnected. When relay DA drops out, contact da 5 releases relay SX , and contact da 6 closes an alternative holding circuit for relay DP,

When relay SX drops out, contacts sxl and sx2 terminate the first pulse of the response signal, and contact sxi closes a control circuit via normally open contact br 5, normally closed contact da 3 and contact dpi in order to actuate relay DR on its series-connected windings (I. ) and (II). On actuation of the relay DR , the contact drl closes a short circuit via the contact bh2 through the winding (II) of the relay, whereby the relay is kept slowly falling, and the contact dr3 closes a control circuit via the normally open contacts br 5 and dp 3 for the purpose Re-actuation of the relay DA on its series-connected windings (I) and (II). When the relay DA is actuated again, the contact da 1 keeps releasing the relay slowly, and the contact ώα 3 initiates the slow release of the relay DR . If the subscriber line receives an acknowledgment signal via the trunk line in question, which is formed by a non-repeating pulse from the signal stream before the relay Pi? drops, the release of the relay XX for the duration of the pulse and its subsequent response have the following result: Due to the inactive state of all of the contact χ χ 2 at the beginning of the pulse, a control circuit for the actuation of the relay CC on its series-connected windings (I ) and (II) and closed for the actuation of the relay AK on its winding (I), the control circuit for the last-mentioned winding also having the normally open contact drl . Upon actuation of the relay AK , the contact ak3 closes a control circuit via the normally open contact cc 5, in which the relay AA is kept in the working state. The contact ak 4 closes a holding control circuit for the relays AK and DR ₁ , this control circuit having the windings (I) and (II) of the relay DR _1, the holding winding (II) of the relay AK and the working contacts da3 and br 5 . The contact ak 6 opens the control circuit of the holding winding (II) of the relay DP. If contact xx2 assumes its normal state at the end of the acknowledgment signal, relay CC is quickly released, since under these circumstances its winding (II) is not short-circuited. When the relay CC is released, the falling back of the contact cc5 into the rest position switches the winding of the relay AX in series with that of the relay AA, so that the relay AX is actuated and the relay AA is held in a control circuit which is via the coil of the relay AA, contact bli3, winding of the relay AY ₁ break contacts sx 3 and cc extends 5 and from there via two alternative paths, once through the normally open contact ak 3 and contact dp 4 and the other time on the make contact xx2. Upon actuation of the relay AX , the contacts axl and ax2 switch off the connection resistors i ?42 and i ?32 from the subscriber line and the trunk sections of the through connection and terminate the disconnected state of this connection by connecting the two sections together.

The subscriber line is now in the state that corresponds to the normal conversation period is peculiar to a speech connection.

If, on the other hand, after the slow release of the relay DR _{1 has} been initiated as mentioned above, an acknowledgment signal is not received before the release of this relay, then the contact dr3 will, on this release, the slow release of the relay DA in the Conduct paths, and the contact drS closes a control circuit for actuating the relay SX. When the relay SX is actuated, the contacts sxl and sx2 begin transmitting a second pulse of the response signal. When relay DA is released, contact da5 releases relay SX . When the relay SX is released, the second pulse of the response signal is ended, and the contact ir 4 closes a control circuit for actuating the relay DR. This method of repetitive transmission of pulses of the response signal is continued until an acknowledgment signal is received, and it causes the actuation of the relay AK and the holding of the relay DR.

Upon actuation of the relay AK , the contacts ak 1, ak 2 and ak 5 change the connection of the transformer TRl ₁ to cause this connection to become a non-directional connection when the receiver is coupled to the subscriber line cores. Thus, during the period in which the subscriber line is in the state corresponding to the normal conversation duration of a voice connection, the audio frequency signal receiver is connected so that it responds by releasing the relay XX to the signal current which is received by the exchange side of the incoming subscriber lines (a signal stream received in this way would not be intended for the receiver), and a non-signal stream which emulates such a signal stream and is received in this way. In the case of the incoming subscriber lines, the arrangement is such that such a release of the relay XX, if it is maintained at least for a predetermined short period of time, the release of the relay AX through the dropout of the relay BH as a result of the short-circuiting of its windings at the contacts xx 1 and brings about the subsequent disconnection of the through connection. This near-end separation protects the audio frequency stream in question from effective incorrect actuation either in the subscriber line in question or in a receiver at the other end of the exchange line.

When the called subscriber or the called operator hangs up, the relay DP is released by the restoration of the normal subscriber line wire polarities on the output side, with the direct current in the ringing loop on this output side being restored from the terminal 29 via the winding (IV) of the Transformer Ti? 5 and the contact aal to connection 28 flows. On this release of the relay DP , the contact dp2 closes a short circuit, depending on the contact dr4, via the series control circuit, which has the rectifier MR 6 and the winding (I) of the relay DP , and thereby ensures that an exact sequence of the operations is completed before any other response of the relay DP to a reversal of the direct current in the ringing loop of the output side of the incoming subscriber line .. takes place. The contact dp 3 initiates the slow release of the relay DA , and the contact dp 5 actuates the relay SX. When the relay SX is actuated, the contacts sxl and sx2 transmit signal current to the speech wires of the long-distance line, and thus the transmission of the impulse of a clear or unambiguous rest signal begins. The contact sx 3 releases the relay AX with the result that the disconnected state of the through connection is restored. Upon the release of the relay DA

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the contact da2 closes an alternative current path in the short circuit existing at this time via the series control circuit, which has rectifier MR 6 and winding (I) of the relay DP , and the contact da.3 releases the relay AK and conducts the slow release of the relay DR in the way. Contact da 5 releases relay SX . When the relay SX is released, the pulse of the pure rest signals is terminated, and the contact sx 3 switches the winding of the relay AX back in series with that of the relay AA, so that the relay AX remains actuated while the relay AA is held, through which the disconnected state of the through connection is ended. When the relay AK is released, the contacts akl and ak2 make the coupling transformer effective again. When the relay DR is released, the contact drZ closes a control circuit for actuating the relay DA. When the relay DA is actuated, the contact da2 opens the short circuit via the series control circuit, which has the rectifier MR 6 and winding (I) of the relay DP . The subscriber line is then in the same state as it is normally shortly before the moment when a called subscriber or a called operator is waiting for a call.

When the caller hangs up, after which the called subscriber or the called operator hangs up, the subscriber line receives a forward signal and responds to it, which is formed by a pulse of the signal stream to which, if or until an acknowledgment signal at the remote end of the Trunk line is received, repeated similar pulses follow, the duration of the pulses being of the order of 2 seconds and the duration of the intervals between adjacent pulses being of the order of 1 second. In order to take effect, a forward pulse must bring about the release of the normally operated relay XX for a sufficiently long period of time to thereby cause relay BH to drop out. The following sequence of actuation then takes place.On the release of the relay XX in response to the impulse, the contact xx 1 initiates the slow release of the relay BH by closing a short circuit, which has the working contacts br 2 and brZ via this relay, and the contact xx2 releases the isolating relay AX and the relay AA and closes a control circuit for actuating the relay CC. When the relay AA is released, the contact aa 1 opens the ringing loop on the output side of the subscriber line.

When the relay CC is actuated, the contact cc 2 closes a ■ holding control circuit for the relay DA. When relay BH is released, contact bhl opens the holding circuit of relay BH, and contact bh3 opens a point in the control circuit of relay AA, in order to prevent any premature reactivation of relay AA . When relay XX is actuated again at the end of the pulse, contact xx 1 releases relay BR , and contact xx2 initiates the slow release of relay XX . On the release of the relay XX , the contact cc 2 slowly releases the relay DA -in the ways, and 4-way contact cc 3 closes a control circuit, which the break contact br 4, and the contact da 4. to operate the relay .SX has. When the relay SX -hin is actuated, the contacts sxl and sx2 transmit a signal stream to the long-distance line, and thus the transmission of an acknowledgment signal begins, which is formed by a non-repeating pulse of such a signal stream. The contact cfß4 maintains a hold control circuit for the relay SX until the relay DA drops out. As long as a stopping criterion (earth) is maintained, through the manual switching cabinet or through the incoming lines, depending on what comes into consideration, the relay in a control circuit via rectifier MR 9 and on the test wire to which terminal 30 is connected Contact sx 5 held actuated. As soon as the state occurs that the relay DA is released and no hold criterion occurs on the last-mentioned test wire, the relay SX is released in order to thereby end the pulse of the output signal. The subscriber line is then in its normal state and is ready for further use.

If the caller hangs up before the called subscriber or the called operator has hung up, the process described above takes place in the modified manner that the opening of the contact aa 1 releases the relay DP and that the relays AK and DR by restoring the normal state released by contact br S.

Assuming a modification of the connections of the three-winding transformer TR 1, the smaller sections or parts of the primary windings (I) and (II) are permanently connected in the subscriber line section of the through-connection, and the ends of the windings which are remote from the small parts or Sections are permanently connected to the line simulation, which is intended to balance the long-distance line, seen from the subscriber line. The secondary winding (III) is connected, as already described above. As long as the relay AK is in its normal idle state, the line simulation is effective, and the transformer creates a directional coupling to the audio frequency signal receiver. During the period in which this relay is in its working state, the line replica is short-circuited and the primary windings then form a transformer with one winding, which creates a non-directional coupling to the receiver. , The aforementioned transformer is. a transformer, which causes a voltage drop from ■ the trunk line. If it is considered to be essential that this voltage decrease should not noticeably disturb the impedance across the subscriber line cores of the subscriber line, seen from the exchange side, the arrangement can be made so that the short-circuiting of the line replica is compensated for (with regard to such Impedance) of the modification of the windings, which are effective in the control circuit of the transformer TR 5, takes place. Alternatively, the effect of lowering the voltage can be minimized by the introduction of suitable small sizes: of. Drag resistance in the through connection. -the official side of the transformer TJ? 1.

Reference is made to FIG, 2 min, which that vorheschriebene -.. Is modified · execution order ,, -wi.e.bereits.iestgestellt in ^ -a schema-

Table circuit is shown, which illustrates a possible use of the invention for the case that a subscriber line forms a subscriber line connection circuit, which is provided for the interconnection of a four-wire "exchange line" and a two-wire exchange control circuit. In this diagram, wires 45 and 46 form the wire pair receiving the signal of the four-wire transmission control circuit, while wires 47 and 48 represent the wire pair performing the transmission. An amplifier A1 is assigned to the pair 45 and 46 and an amplifier A2 is assigned to the pair 47 and 48. The wires 49 and 50 are the wires of the two-wire exchange circuit arrangement. This control circuit is connected between the wires 53 and 59 (which are assigned to the wire pair 45 and 46) and between the wires 57 and 58 (which are assigned to the pair 47 and 48), by means of a differential transformer H, with the required line simulation by a capacitance C 28 is formed, which is connected in series with a resistor R 48. The wires 41 ^ 4 and 42 ^ 4 correspond respectively to the wires 41 and 42 in Fig. IA, the transformer TR IA being such a transformer (corresponding to the transformer Ti? 1 in Fig. IA), which serves to establish the input connection after the Establish audio frequency signal receiver of the subscriber line. The contacts sxlA and sx2A, the resistors R33A and R 34 A and the wires Z9A and 40 ^ 4 each correspond to the elements SxI ₁ sx2, RZZ ₁ RZk ₁ 39 and 40 of FIG. 1A. The contact akia is a contact of a relay corresponding to the relay AK of FIGS. IA and IB. Contacts b 11 and b 12 are contacts of a line blocking relay which is actuated when the audio frequency signal receiver responds to an audio frequency signal stream or to a non-signal stream which simulates such a signal stream. Upon actuation, the contact b 11 closes a short circuit across the wires 53 and 54 (and thereby blocks the transmission between these wires and the wires 51 and 52) and switches a connection resistor. 49 into the control circuit via wires 51 and 52. Upon actuation, contact b 12 shorts out wires 57 and 58 (and thereby blocks the transmission between these wires and wires 55 and 56) and switches a connection resistor I? 50 into the control circuit via wires 55 and 56. The connections of the three-winding transformer TRlA are modified in the manner described in the previous paragraph, with the smaller part of the first primary winding (I) being permanently connected to one of the two subscriber line cores that connect the transformer H and the amplifier A1 , and the smaller part of the second primary winding (II) is constantly connected to the other of these two subscriber line cores. In this case, the line simulation of the previous stage is represented by a resistor i? 47 formed. As long as the contact ^ la is in its normal resting state, this resistance is effective, and the coupling caused by the transformer to the signal receiver is directional, but during the periods in which the contact akia is actuated, so that the resistance R 47 is short-circuited, this coupling is non-directional. Due to the presence of the series resistor R 51 in the connection between the differential transformer H and the transformer TR IA , the effect of the change in state of the contact akia on the impedance of this connection, seen from the transformer H , is reduced to a minimum.

Claims (3)

Claims ·. 1. Circuit arrangement for audio frequency signal receivers in telecommunications, in particular telephone systems, in which the signal receiver, which sits at one end of a trunk line, is coupled to the speech circuit by means of a coupling device, preferably a fork transmitter, which is effective during connection establishment, characterized in that the fork transmitter or the other directionally effective coupling device (77? 1) via switching contacts (ak2, akS) during the speech state of the connection to prevent the transmission of incorrect signals to the subsequent signal receiver is switched in a directionally ineffective manner, for example in that the first signal receiver connects through contacts when incorrect signals arrive (axl, ax2) separates or interrupts. 2. Circuit arrangement according to claim 1, in which the directionally effective coupling device is formed by a differential transformer, characterized in that during the duration of the call, the connections of the windings of the transformer are switched by contacts so that the transformer is no longer than a differential transformer, which is effective in the direction of the received signals, but now as a forward coupling Transformer is working, which is switched to be non-directional. 3. Circuit arrangement according to claim 1 or 2, characterized in that the directionally effective Coupling device in response to receipt of a supervisory response signal is switched to be non-directional. Considered publications:
German Patent No. 944196;
"NTZ", 1956, No. 4, pp. 159 to 167;
"Education sheets of the German Federal Post Office", edition B, 8th year, No. 13/14, pp. 151 to 163. 1 sheet of drawings © 009 510 / 91-5.60