DE596007C - System for the transmission of call or signal currents - Google Patents

Description

Biblioilieek
ur, Ind. Eigenendom

22 MEI 1934

ISSUED ON APRIL 26, 1934

The invention relates to a system for telecommunication systems for the transmission of call or Signal streams of low frequencies or of direct current call or signal streams, via circuit arrangements, which do not transmit these frequencies or transmit them only poorly, especially via the forks of the intermediate amplifiers. object The invention is to improve signal transmission for such systems.

For the transmission of signal currents of low frequency via circuit elements that are only used for the voice frequency transmission are sized, circuits have already been proposed that essentially in a bypass circuit

the mentioned transmission elements exist. With these circuits ensured that only the low frequency signal currents passed through the bypass circuit get lost.

However, the known bypass circuits have several disadvantages. First will when used in equalization circuits through the bypass route connected in parallel the adjustment on the equalization circuits is disturbed and thus the risk of feedback brought about. Second, with the bypass circuits, it is not possible to galvanic Establish conductive connection path for the transmission of direct current signals.

Furthermore, the relatively expensive switching elements for connecting the bypass line required at both ends of the bypass line.

The possibility of the transmission of direct current signals is admittedly with a certain Type of telephone amplifier circuits, namely the so-called single-tube two-way amplifiers, given, but such amplifier circuits are practically no longer used, so that by the invention, which allows it, also with the normal repeater circuits To transmit direct current signals, brought about a significant advance over the known circuits will.

According to the invention, for the transmission of call or signal streams with Frequencies below the transmitted voice frequency band via the forks of the repeaters or via corresponding hybrid circuits, the replication connections of the equalizing transformer via one or more, the Networks that simulate line sections are connected. These networks are like that procure that the equalizing transformer via the connecting current path between the replica terminals only the calling or signal frequencies, but not the voice frequencies

be transmitted. The invention is not only applicable to normal repeater circuits limited, but can be successfully implemented wherever call or signal flows via two hybrid circuits, which are connected to each other by two pieces of double line should.

According to the invention, the replica connections of the hybrid circuits can be of this type are connected to each other so that there is an uninterrupted electrically conductive connection between the corresponding wires of the line sections to be connected. In this case, the transmission of direct current signals is easily possible. the in the connection path, networks to be connected between the replication connections can consist of equalizing transformers, which through networks on certain Frequencies and resistance values are tunable and at the same time as line simulations to serve. Are the two line sections connected to the hybrid circuits in their Resistances equal, so can a common network in the signal transmission circuit be switched on for both line sections.

The further details of the invention and its advantages will become more apparent below detailed description of exemplary embodiments, which with the help of the enclosed Drawings are explained. ·

Figs. 1 and 2 show in principle two-wire amplifier circuits with a signal stream transmission according to the invention. Fig. 3 shows in principle an amplifier arrangement with a single amplifier for both traffic directions.

In Fig. Ι LW and LE are the two line sections which are connected to one another via the amplifier circuit. These two line sections are connected in a known manner in a type of bridge circuit through the equalizing transformer .H ₁ and H ₂ to the amplifier circuit. The currents to be amplified are, on the one hand, passed on in amplified form from the line section LW via the circuit EA, which contains an amplifier 1. to the line section LE . On the other hand, the signal currents to be amplified are transmitted in the opposite direction from the line LE via the circuit WA, which contains the amplifier 2, to the line LW. The windings 3 of the equalizing transformer H ₁ are in series with the connecting wires of the line section LW, while the windings 4 lying in series are inductively coupled to the windings 3. Likewise, the windings 5 of the equalizing transformer Ha are correspondingly in series with the connecting wires of the line section LE, while the windings 6 of the transformer are connected inductively. The input of the amplifier path EA is connected in a bridge to the center taps of the windings 3 of the transformer H ₁ . The output of this amplifier path leads to the windings 6 of the transformer H ₂ - Correspondingly, the input of the amplifier path WA is in bridge at the center taps of the windings 5 of the transformer H ₂ and the output of this path is in series with the windings 4 of the transformer H ₁ , Die Connecting cores of the two line sections LW and LE are further connected via uninterrupted conductive current paths, which consist of the conductors 7, the windings 3 of the transformer Ji ₁ , the windings 5 of the transformer H ₂ , the windings 8 of the third transformer H ₃ , which the latter are connected in series with the conductors 7 between the transformers H ₁ and H ₂ . The secondary winding 9 of the transformer H ₃ is loaded by a resistor network 10. A further resistor network 11, which consists of a resistor connected in series with a capacitor 12, is located in the bridge to the center point of the windings 8 of the transformer H _3.

To achieve the effect according to the invention, it is necessary that the two line sections LW and LE of the system of FIG. The resistance elements of the networks 10 and 11 are selected according to the invention so that the resistances of both the line section LW and that of the section LE are compensated or simulated by the transformer H _{3 and its networks.}

The signal transmission from one line section [LW) to the other (LE) takes place in the same way for both traffic directions, so that it is sufficient to describe this process once. «05

It is assumed that alternating current signal currents of certain frequencies which are to be amplified, for example currents of speech frequencies, arrive on the line section LW. A part of these currents is then transmitted via the windings 3 of the transformer H ₁ via the line EA to the input of the amplifier path and then passed on in an amplified manner by the amplifier. The iao currents inductively transmitted at the same time to the windings 4 remain ineffective, since the amplifier 2 does not allow any transmission in the direction from left to right.

If the networks 10 and 11 are matched appropriately, so that the effective resistance tao of the line section LW is balanced or simulated by the transformer H _3,

of the voice-frequency currents arriving via the line section LW , nothing is transmitted to the line section LE via the auxiliary sstromweg, which runs over the conductor η. Rather, the amplified voice-frequency current flows via the path EA. through the transformer H ₂ to the line section LE. A part of this amplified current, however, is passed through the transformer H ₂ via its ίο windings 5, the line. 7 transferred to the input of the transformer H ₃ . This current is divided in the transformer H ₃ into the series and parallel circuits of the networks 10 and 11 and becomes ineffective when the networks are coordinated accordingly. If the networks 10 and 11 are matched and • the effective resistance of the line section LE is simulated by them, the amplified currents are not via the transformer H ₃ and the conductor 7 to the left to the windings 3 of the transformer H ₁ , ie on the Line section LW, forwarded.

The input resistance of the transformer H ₃ is matched to the effective resistance of the line section LE by coordinating the networks 10 and 11, so that nothing of the amplified current in the output of the amplifier 1 is transmitted through the transformer H ₂ to the input of the amplifier 2. The direct current signal currents are transmitted between the two line sections in both directions of traffic, bypassing the amplifier paths EA and WA via the uninterrupted conductive current path, which consists of the windings 3 of the transformer H, the windings 8 of the transformer H ₃ and the conductor 7 of the windings 5- of the transformer Contains H _2. The capacitance of the series capacitor 12 in the network 11 has such a value that there is no short circuit for the direct current signal currents as well as for the signal currents of lower frequency through the network 11 connected in parallel. ·

The system of Fig. 2 differs from that of FIG. 1 jediglich characterized in that are provided in place of the transformer H ₃ with the networks 10 and 11 of the system of Fig. 1, two intermediate balancing transformer H ₄ and H _5, with the Networks 13, 14 and 15, 16 are interconnected. The resistance elements 13, 14 and 15, 16 are chosen so that through the transformer H ₄ one -. On the one hand, the effective resistance of the line section LW and, on the other hand, the resistance of the line section LE is simulated by the transformer H ₅ , specifically for those frequencies of the signal currents which are to be conducted and amplified via the amplifier. The signal streams of these frequencies in the two traffic directions between line sections LPF and LE are therefore prevented from being transmitted via the auxiliary current path which contains the windings of the equalizing transformers H ₁ , H ₄ , H ₆ and H _2.

The system according to FIG. 2 has the additional advantage over that of FIG. 1 that the effective resistances of the line sections LW and LE do not need to match.

Fig. 3 illustrates the application of the invention in an amplifier circuit which contains only one amplifier for the two ■ »traffic directions. The transmission circuit this figure is similar to known amplifier circuits of this type, differs however, in that there is a corresponding adaptation of the circuit which is achieved that the voice-frequency signal streams to be amplified via the amplifier while low frequency DC and AC signals are transmitted bypassing the amplifier with additional advantages in terms of avoiding echo phenomena and an uneven amplification or transmission of the signal currents in one of the two transmission directions does not occur.

The amplifier circuit according to FIG. 3 contains a single amplifier element 16 and two equalizing transformers H ₆ and H ₇ . The transformer H ₆ has two identical, in series double windings 17, 17 'and 18, 18' and a third, inductively connected double winding 19. The two windings 17, 17 'and 18, 18' are in series between the two sections LW and LE of the line system, which can for example be that of a telephone system and which is terminated by the terminating resistors RW and RE, as shown in dashed lines. The transformer H ₇ has two identical windings 20 and 21 which are in series and a third, inductively connected winding 22.

^: The winding 22 of the transformer H ₇ is located; in the output of the amplifier 16. The input of the. · The amplifier is connected to the points of a circuit which contains the winding 19 of the transformer H ₆ and the winding 20 of the transformer H _{7 in series} . The windings 21 and 20 of the transformer H ₇ , the winding 19 of the transformer H ₆ and the capacitor 23 are in series, and their circuit forms a bridge to the line system LW-LE. A current J ₂ of the same magnitude as the current J ₁ flowing in the winding 19 of the transformer is induced in it. The direction of Stromesl ₂ is indicated by the associated arrow. This current takes its way from the right winding end B of winding 19, left winding end A, input of amplifier i6> center of windings 20

and 21 of the "transformer H." through the winding 20 back to the starting point B. That part of the current which flows into the upper bridge circuit of H ₇ is denoted by J ₃ Connection point D in the upper wire of the transmission line through the capacitor 23, the end point A of the winding 19, via the input circuit of the amplifier 16 to the midpoint of the windings 20 and 21 of the transformer U ₇ , 'through the winding 21 to the connection point E in the lower wire of the transmission line, via winding 17 'of the transformer H ₆ , lower wire of the lineUF, terminating resistor RW, upper wire of the line LW, winding 17 of the transformer 6 back to the connection point D of the transmission line not transmitted, ao because the resistance at the bridge points D and If is equal to the resistance of the windings 17 and 17 by adjusting for the frequencies to be amplified 'and the line connection LW.

As the arrows drawn in FIG. 3 show, the current I _{3 is superimposed on the current J 2} in the input circuit to the amplifier. However, the current J _{3 continues to} flow through the winding 21 in the opposite direction as the current J _{2 flows} through the winding 20. Since the currents J ₂ and J _{3 are} equally strong and counteract one another, no current is induced in the winding 22.

The superimposed currents J ₂ and J ₃ , which flow in the input circuit of the amplifier 16, are amplified and flow as J ₄ through the winding 22 in the output of the amplifier. The current J ₄ has the direction indicated by the strongly drawn arrow J ₄ and induces a current J ₅ in the windings 20 and 21 of the transformer Η _Ί , the value of which is determined by the transmission ratio between the winding 22 and the windings 20 and 21 The current J ₅ flows, as its arrow shows, via the following current path: from the bridge point E through the windings 21 and 20, the winding 19, the capacitor 23 to the bridge point "D. Here it is divided into two equal parts J ₆ and J ₇ divided, which, as 'indicating arrows, on the one hand via the windings 18, 18''und the terminating resistor RE of the line section LE, on the other hand via the windings 17 and 17' which and the terminating resistor RE extend the line resistance LW back to Briickenpunkt e. the current J ₅ , which flows through the winding 19 of the transformer H , induces a current in the windings 17, 17 'and 18, i8' which runs in the same direction over the line system LE as the current J ₁ and how illustrated .by the arrows J. ₈ In the line section LW , the current J _{8 flows} in the opposite direction as the amplified current J ₆ , but in the line section LE in the same direction as the amplified current J ₇ . The current J ₈ can be adjusted by appropriately dimensioning the circuit elements so that it cancels the current J ₆ . This avoids echo phenomena for the participant.

The system of FIG. 3 has the advantage that direct current and alternating current signals of low frequency are transmitted in both directions over the uninterrupted, metallic conductive path between the line section LW and LE without affecting the operation of the amplifier. The capacitor in the bridge circuit, which is connected to points D and E on the transmission line, prevents the short-circuiting of the direct current or low frequency alternating current signal currents.

Claims (8)

Patent claims: 1. System for the transmission of call or signal streams with frequencies below of the transmitted voice frequency band via the forks of the repeater or via corresponding hybrid circuits in telecommunications systems, characterized in that the replication connections of the equalizing transformer for the transmission of the call or signal currents via one or more that simulate the line sections and such Procured networks are connected that only the call or Signal frequencies are transmitted. 2. Transmission system according to claim 1, characterized in that the simulations for transmitting the Rufoder Signal currents, current path an uninterrupted conductive connection so that direct current call or signal currents are also transmitted via this current path can be. 3. Transmission system according to claim 1, characterized in that the means in the current paths to bypass the amplifier in their resistance values so balanced are that a disturbance due to imperfect line balancing, z. B. by feedback within the normal Transmission circuit, does not take place. 4. Transmission system according to claim 1, characterized in that the line simulation at the same time as a suitably matched transmission medium in the signal transmission circuit is used. 5. Transmission system according to claim 1, characterized in that the two connected line sections, if their resistance is equal to each other, the Circuit means are assigned jointly in the signal transmission circuit. 6. Transmission system according to claim i, characterized in that each line section for itself in the signal transmission current path corresponding circuit means for tuning, for the signal current transmission assigned. 7. Transmission system according to claim Ί and following, characterized in that the means in the signal circuit consist of at least one equalizing transformer, to which appropriately tunable networks are connected. 8. Transmission system according to claim 7, characterized in that the signal transmission current path lying windings of the equalizing transformer are tapped in the middle and these taps are tapped together connected in series with a resistor via a capacitor, while the third winding of the transformer is closed as a secondary winding via a suitable network. 1 sheet of drawings