DE495967C - Transmission system with amplifiers serving for the transmission of speech or signal currents - Google Patents

Description

Transmission system used to transmit speech or signal streams with amplifiers To amplify those flowing in longer 'transmission lines Speech or signal currents are used, as is known, amplifier arrangements that are alternately effective in both directions of speech. In order to avoid d @ ate at the fork points of the amplifier casings currents, dIe in one direction flow, get into the return line through reflection and thus echo effects or (with repeated reflection) cause feedback, you have the amplifier circuits provided with echo locks or with feedback locks. For those with eclho locks working amplifier circuits are: both Leitcuigszwexge in the unused state ready to transfer. The incoming speech streams then either cause by means of Relay or by shifting the grid potential to clear the unused ones Direction of speech. When using feedback barriers, however, both line branches are in the unused state not transferable, rather becomes only through the incoming Speech currents themselves. The associated line branch made effective.

The invention relates .ein a transmission system, which a number contains a series of amplifiers which are provided with feedback suppressors are.

According to the invention, a trouble-free passage from one end of the line to the other is ensured that an amplifier or an amplifier office, expediently the amplifier or the central office in terms of speech transmission, by forwarding the control currents that arrive there first and suppressing oppositely directed current surges is designed as a directional for the passage and the blocking of all other amplifiers on both sides. Thereby: Priority can be given to one direction in order to prevent the currents from interfering with each other when the conversation or signaling is started at the same time at both ends of the line. According to the invention, an auxiliary or control circuit running over all intermediate amplifier stations for forwarding or sending control currents for .die amplifiers is provided, which is connected to: the input and output side of all amplifiers in the line. Furthermore, a certain number. be summarized by telecommunication lines to a group, which .A common control circuit (group control circuit) is assigned in multiple circuits. For the control currents, it is advisable to use frequencies that are outside this language range. For this purpose, control current sources of different frequencies are provided on bright 4ed: -tungsadern, which are brought into effect by part of the speech current energy and, via the control circuit to all amplifiers in the Perumeldelleitung. By two each. of these frequencies .is therefore marked a telecommunication line. The control frequencies correspond approximately to the carrier frequencies in the group frequency system of carrier current telegraphy.

The energy to be transmitted from one end of the line to the other becomes a delay circuit in the exit station. led so dar the control currents for commissioning the amplifier earlier via the control circuit reach the amplifiers as the useful currents to be transmitted without any increase the speed of propagation of the control currents is required. There .the control current surge all the way through all the booster stations of bursting. spoken syllable if the beginning of the word is not mutilated. Start now speaking at both ends of the line at the same time, then by appropriate Schaltmiticl the amplifier in: that direction made permeable, their control frequency first reaches the middle station, and @ it becomes the one from the other direction incoming control frequency made ineffective, so that by the first effective Control surges too. the direction of permeability is already opposite directional amplifier is determined.

An example embodiment of a circuit arrangement according to the invention for five amplifier offices is on the drawing in Figs. i to 5 shown. The two Fig. I and 5 show the circuit arrangement for the Power amplifier offices, Fig. 2 and 4 two intermediate amplifier offices and Fig. 3 the Central Office. The five figures, placed side by side, result in the dashed line below Lines 5-5, 6-6, 7-7 three .through telecommunication lines 2, 3 and 4, which one common control circuit i is assigned. In the end stations are in. lines 2 and 3 four-wire one-way amplifiers, while in line 4 in the end stations, @ as in all other intermediate stations, two-way single-pipe amplifiers switched on siüd ,. The amplifiers of power 4 are moreover directed or permanent: permeable "while the amplifiers on lines 2 and 3 in the stations (Abib. 2 to 4) are incomplete or impermeable and therefore for every speech process must be made permeable again.

The operation of the circuit arrangement for the three shown Telecommunication lines is the following: One from the subscriber station i5o via the Line 2 from the end station (Fig. I) to the end station. (Fig. 5) more directional Wave train arrives over the connection line, which ends in a network 156, into the transformer 153 and from here to serve in the double line of the four-wire circuit Ri deployed amplifier zoo. After the reinforcement, part of the energy arrives into one via the normally closed contact of a relay Cl. branched directional amplifier AR, 201, so that the relays A1 and Bi are energized by the direct current generated in this which in your via the contact of the relay C, from the upper double line, des Four-wire of the telecommunication line 2 branched local control circuits lie. That Relay Ar opens a short circuit for the delay circuit at its normally closed contact DP, 2o2, which is formed in any known manner. The relay A1 opens this short-circuit for a sufficient period of time to allow the passage of speech to bring about complete transfer of the endisyllables as well. The relay Bi: opens when he is excited a Kurzscbluß for the Wiechiselstromgenerator 12, whose Frequency f1 as: Identifier of the one end amplifier of line 2 over the frequency band filter 21 and the line 20 are transmitted to the control circuit z will. The response of the relay Bi is timed so that the through. the delay circuit 2o2 causing the delay of the speech currents is sufficient to by the control current, the generator 12 all in the line amplifier ready for use before the first syllable of each word reaches it. That Ratio of the delay time of the delay circuit DP to the switching time of the Relay is chosen so that no syllable is lost.

To be received by: the amplifier set R1 is; The amplifier 203 is made transparent by the control frequency F2 leading each syllable via the control circuit i, in that it actuates the relays C1 and Dl after passing through the filter ioi and the directional amplifier 104 i. In, receiving branch: of the amplifier set; Ri is therefore no delay device required, since z. B. at, Ri the relay D1 timely opens the short circuit behind the amplifier 2o3, while the relay C1 prevents the excitation of the relays A and B1.

In order to render any reflection of speech energy from the subscriber line 150 harmless, it is expedient to equip the relay with a drop-out delay. The fall time must be measured in such a way that the contact is only closed when the reflection wave of the last remainder of the speech transmitted by the receiving branch of R has already passed the amplifier Zoo.

In the control circuit i, the whole. Group of telecommunication lines 2, 3, 4 is assigned together, four-wire amplifier sets R1., R171 R1 $ are now set up in the intermediate stations (Dept. 2 to 4), their amplifiers 32 and 35, 47 and 50, 79 and 8o frequency filters 3o and 31 , 45 and 46, 7 5 and 76 or 33 and 34, 48 and 49, 77 and 78 and a number of oscillation circuits are connected upstream. each frequency band filter BPF is permeable to the entire frequency range of the control frequencies jl, f3, f 7 ... and J., f4, fs ... The oscillation circles; of those in the intermediate offices (dep. 2 and 4) only the circuits 36 to 43 tuned to the frequencies f1, f3 ... to the amplifier 32 and the circuits 86 to 93 tuned to the frequencies f2, f4 ... to the amplifier 8o are upstream, lie in the middle office; the circles 56 to 63 shown in Fig. 3 in each branch of the four-wire line are in front of the amplifier 47 and the circles 66 to 73 in front of the amplifier 50.

During the excitation of the two relays A1 and Bi, each of which is connected in parallel in capacitors 204 and 2o6 to safeguard their excitation duration in order to prevent the word syllables from being shortened, the individual word syllables are transmitted through the transformer 170 to the line 2 At the end, as elsewhere, there is an artificial line 173 at the appropriate points, and via line 2 you get to the amplifier set R2 in the two-way amplifier office (section 2), which is ready for operation in the corresponding direction by the control current surge coming via the control amplifier Ris has been made. The control current pulse passes through a receiver circuit iio which is tuned to the frequency f 1 and which consists of resonance circuits, frequency band filters and a directional amplifier. The control current surge with the frequency il is converted into direct current for actuating the relays A2, B2 and E. The relays A2 and B2 make the amplifier 205 in the speech direction i So to 16o permeable by opening their break contacts A, while the relay E by opening its break contact the receiver circuit. R / 2, iii for one out of the other. Direction with the frequency f2 coming control current surge switches off. The relay E also prevents the amplifier 2o5 from whistling due to feedback or echo formation. The amplifier arrangement R3 in the central office (Abt. 3) corresponds to the arrangement R2 (Ab! H. 2) with the only exception that, in place of the relay E behind the receiver Rf1, z 1 5 in the exciter circuit of the relay A3, B3 a relay F is provided. This relay F is used here as well. otherwise in addition to a control current surge coming from the opposite direction to the respective amplifier stations on the other. To prevent passage. When it is excited, the relay F opens a short circuit at its rest contact for the oscillating circuit 66 tuned to the frequency f2 a current surge of frequency f2 reaches this amplifier set first. If a control current surge from the frequency f1 reaches the intermediate stations R, 4 while D @ ieste is still at rest, i.e. not ready for operation, it causes the two relays A4 and B4 to be energized after passing through the receiver 12o, through which the amplifier 2o9 is ready for operation is made. Due to the excitation of the relay F, the necessary excitation duration of which is ensured by a capacitor 208 connected in parallel, the transmission of a control current surge at the frequency f2 as a result of the opening of the short circuit at the tuning circuit 86 is prevented in all cases. If, however, a control current surge f2 should have entered the intermediate amplifier station R4 before the control current surge f1, the relays C4 and D4 and the relay E are energized, so that the amplifier R4% n is permeable in the direction from 16o to 150. The relay F is not switched off. If a control current surge f1 arrives a moment later, the relay F is energized and the supply of the relays D @ 4, C4 and E is interrupted, so that the relays A4 and B4 can respond as a result of the relay E dropping out. After passing through the central office and the following intermediate office, the control current surge arrives via line 24 (see Fig. 5) in the band-frequency filter 94 and from here into the directional amplifier 97, where it is converted into direct current to operate the relays B5 and 45. The relay B5 opens the short circuit for the amplifier 213 at its idle contact, so that the speech currents pass via the line 2 and the transformer i8o into the amplifier 213 and from there via the transformer 163 into the subscriber station 16o. can. The amplifier arrangement R5 im. Power amplifier office (Fig. 5) corresponds in its structure to the power amplifier station R1, only that the delay circuit 212 and the short-circuit contacts of the relays A3 and C5 are in the other pair of this four-wire. As a result, when relay A5 is energized, a control current surge from subscriber station 16o cannot get into control line i ..

As mentioned, the amplifier station R3 in the middle volume (Fig. 3) to both. Seeing the amplifier a relay F. This has the purpose that the one Control current impulse f 1 or f2, which first reaches the central office, the speech circuit controls. In the pauses between the words, * e sent out by the intercom station i5o control current surges could emanate from the subscriber station 16o and the Amplifier to the left of the middle station in the direction 16o to i 5o permeable do. In order to prevent mutual interference between the control currents, the F-relay receives a drop-out delay which is more than twice greater than is the transit time between two post-hard amplifier stations. Same Success can also be achieved by giving relay B1 a corresponding additional dropout delay issued so that the correspondingly extended control current surge one amplifier station is ready for operation until the next one is ready for operation is made. For this purpose: are; as mentioned above, the capacitors 2o6 and 2o8 relays B1 and F, and similarly capacitors 204 and 2o6 the relays C5 and D5 connected in parallel.

All ready-to-use amplifiers in line 2 remain After G, the conversation flow from i 5o in the direction i So to 16o permeable until the last word outgoing from i 5o has reached subscriber station 16o. Of the Subscriber station 16o can therefore only go out when the subscriber station i5o your speaking for longer than double the transit time, increased by the transit time between two neighboring stations, interrupts. The speaking and control process via dtüe line 2 in the direction i 6o to i 5o takes place in the same way as the one described above for the speech direction i5o to 16o.

The power amplifier devices R6 and IRis built into the line 3, which lead via transmitters 154 and 164 to the Tephieh'mer stations 151 and 161, correspond to the power amplifier stations R1 and R3 of the line 2 in terms of their structure and the circuit arrangement Associated frequencies f3 and f4 are generated by the generators 14 and i 5. The amplifier sets R7, R8, R3 in the intermediate amplifier stations (Fig. 2 and 4) as well as in the central office (Fig. 3), however, are designed in different ways. These offices remain as soon as they are made operational for a direction of passage; ready for operation until a control current surge reaches you from the opposite direction. The recipients z25; 126, 130, 134, 135 and 136 correspond to the receivers i, io, iii etc., only that they are tuned to di, e "frequencies f3 and f4. Two polarized relays 321, 322, also 334, 332 and 341, 342, which are actuated by relays Hl, 01, H2, G2, H3, G3 activated by the control currents. There is one in each intermediate amplifier (Fig. 2 and 4). Relays 127 and 137 to cancel the short circuit of the oscillating circuit 37 and 87 tuned to the frequency f4 and f6. In the central office on both sides of this amplifier there is such a relay 132 and 133, through which the tuning circuits 67 and 57 are brought into effect.

If the subscriber station 151 sends a control current surge through the generator 14 into the control circuit i, after amplification by the amplifier 32 via the receiver 125, it reaches the relay 01 of the amplifier set R7 Relays 321 and 322 move into the position shown. In the repeater station R8 of the Central Office (Fig. 3) the control current impulse fs not only excites the relay G2 and thus the switching of the relays 331 and 332, but also prevents the short circuit for the tuning circuit 67 from opening by the excitation of the relay 132 and a forwarding, one ,. Control current surge of frequency f4. The same will be caused by the control current impulse f 3 in the amplifier station Rg through the relays G3 and 137 . But has a. from the subscriber station 161 or the generator 15 outgoing control current impulse with dfer frequency / "reaches the amplifier Rg before the control current impulse f3, by energizing the relay H3, the polarity of the relays 341 and 342 is reversed and their armature is not connected, so that the amplifier 340 in the direction 161 and 151 is permeable, a control current impulse f3 causes the opening of the short circuit for the voting circuit 87 at the normally closed contact of the relay 137, causes the relay Hg to drop out and prevents the transmission of the current impulse f4. The excitation of the relay G3 on the other hand, the polarity reversal of the relays 341 and 342 causes a change in the direction of the amplifier 340. The switching process in the direction from 161 to 151 is similar to the speech direction from 15I to r61.

The amplifier sets Rll to R15 used in the telecommunication line 4, which are permanently operational, are all identical to one another. Their permeability in every direction is indicated by the opening of relay contacts. The amplifiers 401, 421, 431, 44I> 451 are all single-tube two-way amplifiers. In the end station R11 z. B. is the input side of the amplifier 401 by means of the transformer 402: on the one hand, with, the transfer carrier 155 and on the other hand with the transformer 172 connected. The output side of the amplifier is also connected to both the transmitter 172 and the transmitter 155 via the transmitter 404 @. The first of these connections contains one. Delay circuit: s 4o6, which is short-circuited by the contact of a relay All and! Can be opened by the contact of a relay F11. The second of the four connections can serve through. Contact of a relay C11 short-circuited and: opened by the contact of a relay G11. The same is done for the third and fourth connection through the contacts of the relays Dii, Hfl, B11 and EI. If the first and fourth of the connections are effective, the amplifier is permeable in the direction from 152 to 162. On the other hand, due to the effectiveness of the second and third connection, it is permeable in the direction towards the subscriber station 152. The above relays are controlled by the directional amplifier 407. The relays All, Bit, Cif and DIi are polaxized, so that in the absence of an excitation current, the armature of each of these relays is actuated by one of its windings until the other winding comes into effect. The two directions are indicated by arrows. In addition to the relays mentioned, relays J "and Kli are also provided in the end stations, two relays J13 in the middle station, while only one relay J12 or J14 is provided in each of the intermediate stations.

Assuming that speech transmission takes place from 162 to 152, part of the speech energy entering via the transmitter 165 is converted by the directional amplifier 447 into direct current for actuating the relays C15, F15>A15>K15> D1: 5>E15> B15. The short circuit at the generator 17 is opened by the excitation of the relay K15, so that a control current of: the frequency f8 is sent over the control line 1.

Appropriately, the relays E15 and F15 should open before C15 and Di5 come into effect to prevent the amplifier from whistling. Because during the Relocation of the anchor from. Cis, A15, Dis and Bis are all four for a short time Partial routes from R, 5 permeable, so there is the possibility of self-production. is. As soon as the relays A, 5 and B15 have closed their contacts, the The risk of whistling eliminated and the relay contacts El r, and Fis opened is no longer required. For this purpose ice and FIS capacitors are used with the relays 46o connected in series, so only the inrush of the from directional amplifier 447 supplied control current is effective as charging current of the capacitor. But about the To maintain constant currents for the other relays, ice and F sharp are inclusive of the capacitors 46o bridged by resistors 461.

As soon as: the control current from the frequency f8 via the receiver 145, Rfs reaches the intermediate amplifier station R14, the relays A14, F14, C14, B14, E14, D14, which are arranged according to the relays A15 ... in station R15, are thereby excited are. On the other hand, when the control current arrives at beer middle station R, 3, the corresponding thing occurs. Relays A13, F13, C13, B13, ice> Slide still relay J13 to respond; J13 removes the short circuit for the resonant circuit 58, which is tuned to f7, so that the passage of the control current f7 is prevented.

If the control current f8 the intermediate amplifier set R12 before one of the, control current f7 coming on the left is reached, then via the receiver 141, RA düe Relays J12, A12> F12> C12, B12> E12> D12 energized.

If, however, the control current f7 reaches station R12 before Es, relay contacts G12 and H12 are temporarily switched over, while the contacts of A12, C12, B12, D12 remain in the position shown or are switched into this. In spite of this, the control current f8 arriving later retains the predominance, since after passing through the receiver 141 it actuates the relay J12 and, by switching on the blocking circuit 38, prevents the further transmission of f7. In addition, the relays @ i2 ... are operated by fs in such a way that the amplifier set R12 can transmit in the direction from right to left. .

A whistle from the amplifier is heard closing the contacts of relays A12 and B12 prevented when opening E12 and F12. if but relays H12 and 012 do not have enough time to close. of their contacts before the other. If relays are energized, the beginnings of words are mutilated possible if the delay in the delay circuit is not made large enough is. It is now. Assuming that the relays G12 and -H, 2 are just energized while the control current J $ by the excitation of the relay J12 a transmission of the control current f 7 prevented. The avoidance of control currents f7 and f $ can only be used to the right of the amplifier meet at a distance, which @ the @ er current surge during half the fall time the relay H12 and 012 has traveled. The increased switching time of the amplifier would then be equal to the excitation time reduced by half the release time of the relays H12 or be a gig. If the current surges f $ and f7 just meet in the amplifier q.21, the relays H12 and -G12 do not open their contacts before the Current impulse f7 is interrupted by the excitation of relay J1. By the control current f8, not only the amplifier 401 in the direction 162 becomes transparent in the end station R11 made, but also by energizing relay J11 of directional amplifier 407 switched off.

How the amplifier arrangement works for the passage of speech in the direction from 152 to 162 is readily apparent from what has been described above Occurrence.

Claims (1)

PATENT CLAIMS: i. This transmission system is used to transmit speech or signal streams with several amplifiers one behind the other, which are made ready for operation by the speech or signal streams (Rückkoppl'tmgs's'p; exrung), characterized in that - an amplifier or an amplifier station, expediently the one in the Central amplifiers (or: the 1 \ üttel = t), by forwarding the control impulses that reach it first and suppressing impulses directed in opposite directions as directional for the passage and blocking of all other amplifiers on either side. 2. Transmission system according to claim i, characterized in that one direction is given priority by suppressing the control currents emitted simultaneously in the opposite direction in order to prevent mutual interference of the control currents while simultaneously speaking at both lines. 3. Transmission system according to Claim and, characterized 2 in a bad all Verstärkerstatknen-leveling Steuerstrornkreis (i) däß provided. that is connected to the input and output side of all amplifier devices in the line. -q. transmission system according to claim. i to 3, characterized in that .the control circuit - (i) for a certain number. of telecommunication lines combined to form a group is common (group control circuit) and is connected to all telecommunication lines of the group in a single circuit. §. Transmission system according to claim q., characterized in that a local control circuit (directional circuit) is provided at each amplifier, which the amplifier station is connected to with your group control circuit. 6. transmission system according to claim 5, characterized in that only the local control or -Richtkreis is provided in .den end stations _ (Dep. I = undt_ 5). Transmission system according to Claims i to q., Characterized in that each telecommunication line is assigned two frequencies which are expediently outside the voice frequency range; of serve each, one for one direction of traffic. B. Transmission system according to claim 7, characterized in that an alternating current generator is provided in the two end stations on each line, the activation of which is carried out by means of a directional amplifier through the speech energy (from b. I and 5). G. Transmission system according to claim 8, characterized in that - that in the. Speech circuits in the traffic direction a delay circuit is switched on (DP in Fig. I and 5). 10. Transmission system according to claim 5 and 8, characterized in that, in the end offices, the alternating current generator associated with a line is connected to the local control circuit. i i. Transmission system according to Claims 3, 7 and 8, characterized in that band filters (BPF) are provided in the group control circuit for the group frequency range and oscillation circuits tuned to the individual frequencies belonging to the frequency range. are (Dept. z, 3 and q.). 12. Transmission system according to spoke 3, q. or ii,, characterized by the fact that the group control circuit is designed as a four-wire amplifier circuit (Fig. a, 3 and q.). # i3. Transmission system according to claim 12, characterized in that in the central office in each branch of the V; lex wire the amplifier (R17) is preceded by oscillation circuits for all frequencies which are assigned to the lines of a group for a speech direction, while in all intermediate offices (R ", R, .8) only the branches leading to the central office are provided with oscillation circles; .which are tuned to the frequencies of the group area assigned to the corresponding traffic direction; (Fig. A, 3 and ¢). 14- Transmission system according to claim 13, characterized that a short circuit is provided for each floating or blocking circuit, which is controlled by a control pulse from the opposite direction (fig. 2, 3 and q.). 15. Transmission system, according to claim 1.1, characterized in that in the central office on both sides des, amplifier switching elements (relay F) are provided, through which on the one hand the transmission of a control impulse causes and on the other hand the Du negligence of the amplifier in the direction corresponding to it (Ab @ b ,. 3). . 16. Transmission system according to claim z and 15, characterized in that the switching element for the previous direction of speech is equipped with drop-out delay, which is preferably greater than twice the propagation or transit time of the bar pulse to the next amplifier. 17. Transmission system according to claim i or the dependent claims, characterized in that in the lines of a group and also in one and the same line amplifiers of different types, such as single-tube two-way amplifier in four-wire and two-wire circuit, are present, which are either ready for use in remain permeable in this direction or be made ready for operation anew for each speech passage. 18. Transmission system according to claim 13, characterized in that the activation and deactivation of these amplifiers or their setting in. The end stations by a relay combination consisting of two relays (A, B and C, D), of which each group is mutually influenced, and that the relay serving one direction of passage (e.g. A, B) is also used to generate and propagate the control pulse for the other amplifiers in the line. i9. Transmission system according to Claim 18, characterized in that only one or the other pair of relays receives current via a directional amplifier. 2o. Transmission system according to claims 13 and 18, characterized in that a switching element (relay E) is provided in the intermediate stations in order to prevent both relay pairs (A, B and C, D) from responding simultaneously when a control pulse is received from both directions (Section 5 in Fig. A and q.). 21. according to claim 13 and 18, characterized in that the switching elements determining the priority of the forward direction (e.g. relay A) with drop-out delay (parallel connection of a capacitor) are permitted. 2z. Transmission system according to Claim 15, characterized in that, in the case of ready-to-use amplifiers, double combinations of switching elements, two for opening and two for closing, are provided, some of which work faster than the others.