DE677043C - Echo and feedback lock - Google Patents

Description

Τ «5 · ή",

S ^ "ISSUED ON
June 17, 1939

The invention relates to echo and

Feedback barriers in telephone systems with two transmission paths, one of which to prevent whistling at least one. Route is permanently blocked.

Such a system is, for example, the two-wire amplifier operation, in which it is known in the case of inaccurate adjustment of the fork transfer, a whistling sound can easily be heard if

to both transmission paths combined in the fork transmitter released at the same time are.

Such systems also include, for example, the so-called hands-free systems, in which a microphone and a loudspeaker are connected to a telephone line by means of a fork transmitter are and with which, if at least one transmission path is not permanently blocked, a whistling both 'as a result of insufficient Adjustment of the fork transmitter as well as acoustic feedback between the loudspeaker and the microphone arise can.

It is well known that feedback locks are used to eliminate the tendency to whistle, according to the principle of shifting the grid potential of the amplifiers of the transmission paths or the relay control of the opening and closing or make contacts work. These feedback locks usually act in such a way that the normal in the rest position blocked first path opened in it at the beginning of the voice transmission and at the same time the second normally in the rest position The released path is blocked, bridging the gap between the individual words and syllables Pauses the return of the system to the rest position when terminated or interrupted speaking in the first way with a certain delay, the so-called after-effect time takes place so that the system has sufficient operational safety and stability and not as a result of the mentioned pauses continuously from the operating to the idle state and vice versa is reversed by leaps and bounds.

The known feedback locks have the disadvantage that an interruption of the speaker through the intercom, the so-called break-in, with a pause or weak syllable of the former not can take place immediately, but only after the after-effect period has expired, which often results in a whole word part is suppressed and unpleasant distortions of the language arise.

The invention is now directed to overcoming this disadvantage.

The invention relates to an echo and feedback blocker in telephone systems with two transmission paths, at least one of which is blocked in the rest position, and with voice-operated devices

services that release one of the paths for transmission in the operating state and lock the other at the same time, with the return to the rest position upon termination 5 or interruption of speaking only takes place after an after-time period has elapsed, which lasts longer than the pauses between words and syllables.

According to the invention, the blocking

> o and release of the transmission paths from dry rectifiers existing damping networks 8 and Ii causes their Attenuation is controlled by voice-operated devices 7 or 10 * the except from

the speech streams causing the release of a transmission path also from 'the speech streams of the other path over control paths 14 and 19 operated in this way be that with a pause or weak syllable in the first way this within a Locked and released the second way for a much shorter time than the after-effect time and that to compensate for the effect of the echo currents the voice-operated Devices via control paths 15 and 20 further currents from the first transmission path the effect of which lasts a little longer than the echo transit time.

The voice operated devices are preferably adjusted so that in the speaking pauses on the first path also from only weak streams of speech of the second path cause a break-in within a period of time which can only be slightly longer than the running time of the speech streams of the echoes originating from the first path, but much shorter than the normal after-effect time is.

The invention is explained in more detail below with reference to the exemplary embodiments shown in FIGS.

In Fig. Ι is the circuit diagram of a hands-free system connected to a telephone line shown according to the invention.

A microphone 1 and a loudspeaker 2 are by means of an equalizing transformer 4 to a Telephone line 3 connected, the usual line simulation denoted by 5 is. In the microphone circuit, the amplifiers 6 and 7 are in series with a changeable one Damping network S, amplifier stages 10 and 12 in the loudspeaker circuit in series with a variable damping network 11 and a volume control arrangement 9. The amplifier tubes 7 and 10, respectively serve not only as' amplifiers for the speech streams, but also as voice-operated devices, the damping networks 8 and 11 in a manner to be described steer. These networks are strongly attenuated in the rest position; the microphone and the Loudspeaker paths are practically blocked, so that even with poor alignment of the transformer 4 a whistle over the acoustic leading from the loudspeaker to the microphone Feedback path can not occur in the rest position.

So that the speech streams can clear their path, which is blocked in the rest position the output of the tube 10 via a control path 13, which has a variable damping network 16 and a rectifier 17 in Contains series circuit, with the input of the tube 7 and vice versa the output of the the latter tube via a control path 18, which has a variable damping network 21 and a rectifier 22 in series connected to the input of the tube 10.

The networks 16 and 21, which are also controlled by the voice-operated devices 7 and 10, but are only weakly attenuated in the rest position, have the purpose of preventing incorrect actuation of the tubes 7 and 10 by echo currents.

. The circuit explained so far works in the following way: The speech currents emanating from the microphone are amplified in the amplifier stages 6 and 7, flow, since the path to line 3 via network 8 is initially still blocked, via control path 18, whose network 21 is only weak is attenuated, are rectified in the rectifier 22 and, by shifting the grid potential of the tube 10, cause the attenuation of the networks 11 and 16 to increase, while that of the networks 8 and 21 is decreased. The microphone currents can now reach the line 3 via the network 8, while the path 13 to the tube 7 through the network 16 is blocked for the echo currents coming from this line and, due to the high attenuation of the network 11, whistling due to acoustic feedback is also excluded. _Io5

In a corresponding manner, speaking currents coming from the line 3 via the control path 13 cause the tube 7 to increase the attenuation of the networks 8 and 21, that of the networks 11 and 16 is decreased, so that the path to the loudspeaker 2, the microphone path and the control path 18 are blocked and thus a whistling and undesired actuation of the tube 10 due to the acoustic feedback _path and control path 18 from the loudspeaker to the microphone is prevented.

When the speech streams the devices Press 10 and or 7, stop, the released transmission paths are blocked again. For reasons of

operational reliability and the transmission quality of the system, it is now desirable that this Do not block during every pause between words and syllables 5 or occurs during a noisy syllable, as whole parts of the word are lost and unpleasant distortions can arise. For this reason, the system returns to its rest position at

ίο a termination or interruption of the Speaking in the released transmission path with a certain delay, which is the pause between the individual words and bridged syllables.

However, this after-effect time now has the disadvantage that a speaker at the one end of line 3 cannot answer until the speaker he is listening to, has been silent for a period of time that is longer than the after-effect.

The voice-operated devices 7 and 10 are used to eliminate this disadvantage each equipped with a control path 14 or 19, which the output of each device connects to their entrance. The effect of these control paths, which will be explained in more detail later is that the device 10 actuated by the microphone currents Speech streams coming over the line 3 via the control path 19 almost instantaneously in their normal state is restored and the attenuations of the four networks are restored accept their resting value. Correspondingly, the device 7 actuated by the speech streams coming from the line is through Microphone speech currents via the control path 14 almost immediately back to their normal state brought.

As a result, by resetting the system to idle, the response voice streams can clear either path 13 or 18 and cause one of the voice operated devices to clear the response path. In this way it is possible to break in the response voice streams without having to wait for a pause in the conversation of the first speaker.
In order to prevent echo currents from causing a break-in, two further control paths 20 and 15, shown in broken lines, are finally provided, the exact circuitry and mode of operation of which will be explained later. With reference to FIG. 1, it should only be stated that the speech currents flowing in the paths 20 and 15 respectively compensate the echo currents flowing in the paths 19 and 14 with regard to their effect on the device 10 and 7 and that this compensation effect is only takes about longer than the echo transit time, i.e. it is much shorter than the lag time to bridge the pauses between the words and syllables.

The arrangement is now made so that the effect of the paths 20 and 15 Compensation currents flowing to the voice-operated devices are always greater is than the effect of the corresponding echo currents, so that also normal response speech currents except during a pause, can only break in during a weak syllable of the first speaker, while during a pause, for example one between two syllables or two words, after the end of the Echo compensation effect also by a subsequent very rapid break-in only weak response speech currents can be caused.

The basic circuit shown in Fig. 1 is shown in more detail in Fig. 2, the corresponding switching elements and connecting paths in both figures are provided with the same reference numbers. As can be seen from FIG. 2, there is each of the four attenuation networks from a plurality of dry rectifiers included in the longitudinal or transverse branches of the networks are arranged. The attenuation of every network, becomes their alternating current resistance by means of a flowing through the rectifier determining direct current controlled.

Attenuation networks of this type are already known. It should therefore only be mentioned here that depending on the choice · the bias applied to the rectifiers or networks Even a slight change in the controlling direct current can result in a considerable or also only a slight change in attenuation. ·

The microphone is connected to lines 40, the loudspeaker to lines 41. The damping networks 16 and 21, which are made up of the series connection of two If there are subnetworks, the control direct current is fed into terminals 23 and 24 or 25 and 26, the simple damping networks 8 and 11 at terminals 27 and 28 or 29 and 30 supplied.

To determine the course of the control current in the no To be able to better follow individual networks, is in connection with FIG referring to FIG. 4, in which all parts of the circuit which are essential for the control of the damping networks according to Fig. 2 are shown.

The two voice-operated devices 7 and 10, each consisting of an electron tube exist, control the attenuation of the networks shown as rectangles by means of a bridge arrangement, the tubes 7 and 10 and the ohmic resistors 31

and 32, the latter of which can be changed (see FIG. 2), in adjacent branches. The anode battery 33 is connected diagonally across the bridge in that its positive pole is connected to the junction of the resistors 31 and 32 and its negative pole is grounded and thus connected to the cathodes of the tubes 7 and 10, which are also grounded. In the other diagonal between the corner points 34 and 35, the damping networks are in series with a choke coil 36 serving to reduce the alternating current ripple in the control circuit (FIG. 2). The network terminals 28 and 30 are connected to the positive pole of the battery 33 via an ohmic resistor 39, and the terminals 26 and 27 or 29 and 24 are grounded via ohmic resistors 37 and 38, respectively.

In the idle state, the bridge is balanced by means of the resistor 32, so that the Points 34 and 35 are equipotential points and no current flows between them. It flow but in the following ways direct bias currents through the individual networks:

"■ i. + -Pole of the battery 33, 31, 34, 25, network 21, 26, 37, earth,

2nd + -pole of the battery 33, 39, 28, network S, 27, 38, earth,

3rd + -pole of the battery 33, 39, 30, network 11, 29, 38, earth,

4. + -pole of the battery 33, 32, 35, 23, network 16, 24, 38, earth.

These bias currents are of such magnitude and direction that the networks 16 and 21 have a very high attenuation and can be considered blocked while the networks 8 and 11 have only a weak attenuation and are considered released can.

The change in attenuation of the networks is now due to the disturbance of the bridge equilibrium causes, between points 34 and 35 in one direction or the other a compensating current flows which controls the attenuation of the networks. This control current is essentially superimposed on that which is already present in the networks stationary and relatively small bias currents compared to the control current. If the bridge equilibrium is disturbed in such a way that the control current in direction 34 until 35 flows, then this current in the networks 21 and 11 has the same direction like the bias current, so that these networks remain released or blocked, while he is opposite in networks 8 and 16 Has the same direction as the bias current and thereby the network 16 locks and releases the network 8.

It is important that the network 16 be locked before the network 8 is released, because in the opposite case, the Line 3 coming, originating from the speech streams flowing in the network 8 Echo currents or those resulting from poor adjustment of the transformer 4 in the loudspeaker path arriving streams via the control path 13 and the still released network 16 interrupt the activity of the amplifier 7 and would create a state in which the transferred conversation would alternate as a result of the blocked and released network 8 is continuously interrupted and restored accordingly.

The correct order in the attenuation switchover the two networks is now due to the difference in the bias currents and by connecting capacitors and chokes in the bridge circuit achieved. Since the bias currents of the two networks 8 and 16 are relatively opposite Directions flow (see FIG. 2) and also differ in value from one another as much as possible and since the capacitors and chokes are also instantaneous Prevent switching, it results that the network 16 before the release of the network 8 is blocked. In other words, it becomes the critical state at switching from high to low attenuation and vice versa takes place first in Network 16 and then reached in network 8.

The presence of the mentioned capacitors and chokes in the bridge circuit also has the effect that with small changes in control current both networks tend to be locked rather than unlocked at the same time to be, whereby the correct operation of the system is guaranteed.

If the bridge balance now disturbed in such a way that the control current in the direction of flow 35 to 34, then the control current flows in the networks 16 and 8 in the same direction as the \ ^r orspannungsstrom so that these networks remain enabled or disabled. In the networks 11 and 21, however, the control current flows in the opposite direction as the bias current, so that the network 21 is blocked and the network 11 is released. The bias currents are again so different in magnitude and direction that the network 11 is blocked before the network 21 is released.

The disturbance of the bridge equilibrium, in which the control current in the direction of 34-35 flows, is caused by the fact that the currents coming from the microphone have the negative Reduce the grid tension of the tube 10, so that their anode direct current and thus the voltage drop across the resistor 32 grows, and in this way the potential

of point 35 compared to that of point 34 decreases.

The reduction of the negative grid bias takes place in such a way that the in the amplifier stages 6 and 7 amplified microphone currents via the control path 18 through the network 21 ', in the rectifier 22 are rectified and to the capacitors lying in the grid circle of the tube 10 42 generate a voltage which counteracts the negative bias given by the battery 43. If the Speech currents in control path 18 are interrupted or cease, the capacitors discharge 42 across resistor 44, and the grid voltage of tube 10 increases again their resting value. The resistor 44 and thus the time constant of the discharge circuit is now chosen so that the discharge takes place only as quickly as to achieve the already The after-effect mentioned above is required, which means that the the transmission path released for transmission due to the natural pauses

between the words and syllables of the language prevented.

For the purpose of a quick break-in, there is a second one of the capacitors 42 for the capacitors above-described first discharge circuit independent discharge circuit created that normally is high resistance, but made low resistance by the response speech currents coming from the line 3 via the control path 19 and in this case an almost instantaneous discharge of the capacitors 42 brings about. This second discharge circuit contains a low resistance 48, the task of which will be explained later, and a rectifier 45, which as a result of him has a very high reverse resistance due to one of the biases given by the batteries 43, so that the second discharge circuit can normally be viewed as blocked. Those arriving via route 19 Response talk currents are rectified in rectifier 45 and act as a bias of the rectifier against. Provided that the amplitude of the response speech currents is sufficiently large, the bias voltage and thus the blocking state of the rectifier is overcome, so this is made low-resistance and a very fast discharge of the capacitors 42 caused by the second discharge circuit.

The mentioned resistor 48 in the second discharge circuit is used to generate an additional one Bias for the rectifier 45 for the purpose of compensating for the over

- line 3 incoming \ ^r on the Mikrophonströmenherrührenden echo currents as that might exactly be over the line 'response speech currents arriving from collapsing effect. For this purpose, part of the microphone currents is diverted from the output transformer of the tube 7 via path 20, rectified by rectifier 46 and used to charge two capacitors 47, to which the resistor is assigned as a discharge resistor. The voltage on capacitors 47 is directed to add to the bias voltage of rectifier 45; the currents flowing via the control path 19 that want to break in must therefore overcome the increased bias voltage of the rectifier. The arrangement is such that normal response speech currents can only overcome this increased bias during a weak syllable or a pause in the microphone currents and cause a break-in. Furthermore, it is ensured that the voltage generated by the echo currents via the path 19 on the capacitors 47 is always smaller than the compensation voltage produced via the path 20 by the microphone currents on these capacitors. In this way, a break-in by echo currents is excluded.

Resistor 48 is now dimensioned such that the time required to discharge the condensate 47 is only very slightly greater than the echo transit time, which is generally only a few thousandths of a second and is thus considerably shorter than the system's after-effect time given by resistor 44. As a result, in the event of interruptions in the microphone speech, for example in the pauses between the individual words and syllables of a normal speed of speech, after the echo compensation effect, which is only ten times very short, also relatively weak response speech currents can subsequently cause a collapse, since they only act as the bias voltage of the rectifier 45 need to overcome, the ¹ ^ S comes from the corresponding battery 43. The above explanations related to the case that the equilibrium of the direct current bridge arrangement controlling the damping networks is disturbed by actuation of the amplifier tube 10 and a control current flows in the direction 34-35. When the device 7 is actuated by speech currents coming from the line 3, the control current flows in reverse in the direction 35-34. The switching operations in this case correspond to those described so far. The currents derived from the output of the tube 10 via the controller 13 flow via the network 16, are rectified by rectifiers 17 and generate one of the voltages of the grid batteries 50 on the capacitors

counteracting voltage which can be discharged via resistor 60. In the second discharge circuit of the capacitors 49 is the rectifier 51 and the resistor 54, wherein the rectifier bias generated by one of the batteries 50 by about Response voice currents flowing along path 14, which are rectified in rectifier 51 and the capacitors 53 charge, overcome and discharge the very quickly Capacitors 49 can be effected. The effect of the echo currents is through about the control path 15 coming from the output transformer of the power amplifier stage 12 for the speaker currents compensated for currents derived in the rectifiers 52 are rectified and the capacitors 53 are charged in the opposite direction to the echo currents.

The invention is of course not limited to the control of the damping networks takes place by a bridge arrangement. Rather, any other desired arrangement can be used for this, in which one Number of networks shared by the same control voltage or the same Control current is regulated and in which the bias potentials or currents of the various Networks change in any way.

The application of the invention to a two-wire amplifier system is shown schematically in FIG shown. After the preceding discussions, the representation chosen in the figure, free of details, appears sufficient. The parts corresponding to the previous statements are the same Way designated. The line 3 is with the forward response current paths through the Equalizing transformer 4 coupled. The talk current path contains a balanced one Four-wire amplifier 61, a normally-locked attenuation network 8 and a Transmission amplifier 62. The answer

■ 5 current path consists of a balanced Four-wire amplifier 63, a normally-locked attenuation network 11 and a Transmission amplifier 64. The attenuation of the networks is in the same way as controlled in the circuits explained above. Serve in the present case however, the voice-operated devices 7 and 10 exclusively for control purposes, that is not at the same time as a transmission amplifier; the voice stream transmission paths and the Control current paths are completely separated from each other.

The invention is not self-evident

only to the illustrated embodiments

'o limited because the circuits in detail can still be modified without, however, affecting the essence of the invention is departed. For example, the invention can not only be applied to two-wire transmission systems, but also. on single-lead circuits that are not effective at the same time may apply. * ■

An example of the application of the invention to speak-out circles or to two single-lead circles is the case of a three-party meeting with two separate participants at one end of the line and a participant at the other end of the line, in which case the damping networks would have to be arranged and controlled so that two subscribers at the same end of the line cannot control the line at the same time can take over. In other words, when a participant speaks, the line should be blocked for the other participant.

Claims (6)

Patent claims: i. Echo and feedback lock in 8s Telephone systems with two transmission paths, at least one of which is blocked in the rest position, and with voice-operated devices that release one of the paths for the voice transmission in it and at the same time the an- "" '"* block them, and in which the return to the rest position after termination or interruption of speaking only after An after-effect time has elapsed that lasts longer than the one between the Words and syllables occurring pauses, characterized in that the blocking and release of the transmission paths by means of dry rectifiers Damping networks (8 or 11) causes whose attenuation is controlled by voice-operated devices (7 or 10) which, in addition to causing the release of one transmission path Speech streams are also actuated in this way by the speech streams of the other path via control paths (14 or 19) that with a pause or weak syllable in the first way this inner no half of a much shorter time than the after-effect is blocked and the second way is released and that to compensate for the effect of the echo currents voice-operated devices via control paths (15 or 20) further currents are supplied from the first transmission path, the effect of which is somewhat longer lasts than the echo transit time. 2. echo and feedback lock according to claim i, characterized in that the damping networks (8, 11, 16, 21) all of the one diagonal of a bridge arrangement balanced in the rest position (Fig. 4), which are fed in the other diagonal by a battery (33) and those in neighboring branches on the one hand the voice-operated devices (7 or 10), on the other hand, contains ohmic resistances (31 or 32), and that the bridge is unbalanced during speech transmission and itself that flowing through the damping networks in the rest position, pretensioning them A compensating current is superimposed on currents, which changes the attenuation of the networks in the required manner. 3. Echo and feedback lock according to claim 1, in which the re-locking ■ the released first path from the discharge of two of the rectified Speech currents of the first path of charged capacitors (42 or 49) depends, which normally have a high, the resistance (44 or 60) ensuring the required post-action time takes place, characterized in that in order to enable the capacitors to break in, a second of the first independent, normally high-resistance discharge circuit is created through the speech currents of the second path via the control path (19 or 14) are low-resistance can be made and thereby causes an almost instantaneous discharge. 4. echo and feedback lock according to claim 3, characterized in that in the second discharge circuit a normally in the blocking state as a result of a corresponding bias voltage Rectifier (45 or 51) is switched on and the discharge circuit supplied, rectified by the rectifier speech currents of the second Way overcomes the bias and thus the blocking state of the rectifier p and make the discharge circuit low-resistance. 5. echo and feedback lock according to claim 4, characterized in that in the second discharge circuit further con- • Capacitors (47 or 53) are located by the speech streams of the first path in such a way are chargeable that they counteract the elimination of the bias of the rectifier (45 or 51), and that this counteraction by means of a correspondingly selected discharge resistor assigned to the capacitors (47 or 53) (48 or 54) is maintained for a time that is slightly longer is than the transit time of the echo originating from the speech streams of the first transmission path, so that the effect the echo currents are compensated for on the second discharge circuit. 6. echo and feedback lock according to claim 4 to 5, characterized in that that the charging of the capacitors (42 or 49) caused by the speech currents of the first path the negative grid bias of an electron tube (7 or 10) serving as a voice-operated device is reduced and thus their anode direct current is increased and that the electron tube is expediently the one for amplification the amplifier or its output tube required for the speech streams. 1 sheet of drawings