DE565904C - Two-way transmission system - Google Patents

Description

There are already known arrangements in electrical two-way transmission systems which tubes in accordance with the level at a given point in one The circuits are controlled to adjust the gain or attenuation within the To regulate transmission system. Such transmission systems are generally used to measure the voltages of the signals, the long transmission paths, for example Submarine cables, or the airwaves, are pushed on within the predetermined ones To keep boundaries. In such systems, it is useful and already known that the effective gain or effective attenuation that occurs during transmission via the The loop formed by the two circuits is created, to be kept as constant as possible, d. H. if the attenuation increases in one of the circuits, it is appropriate to reduce the attenuation to decrease accordingly in the other circuit and vice versa.

In a two-way electrical transmission system of the type mentioned, that in both Circuits with compensation tube circuits that depend on the potential of a point in one of the two circuits can be controlled jointly is, according to the invention, the one compensation tube circuit is in series with the one Circuit and the second compensation tube circuit in parallel with the second circuit switched so that the attenuation increases in one circuit while it decreases in the second circuit. Preferably two tubes are used in each circuit, and the anode-cathode-S route the two tubes in each circuit are connected in push-pull, with the cathodes of the tubes are connected to each other. This arrangement makes it possible to use the To adjust circuits in such a way that their potentials, referred to the earth potential, are symmetrical because the cathodes are with each other and with theirs in a neutral point heat sources lying in the circuit are connected.

The tubes are in accordance with the potential in one point in one the circuits through which the transmitted signals flow are controlled, after it passes the tube or tubes assigned to the circuit in question to have.

The control electrodes of all tubes are preferably connected to one another via a Capacitor connected to the specific point in one of the circuits. Between the point in the circuit whose potential is decisive for the control of the tubes,

and the capacitor a limiting relay arrangement can also be provided, so that the potential of the capacitor across the circuit in question is only changed can be if the potential in the point concerned is a predetermined one Value exceeds.

The capacitor can also be connected to a tube circuit, the Impedance in accordance with the potential at the mentioned point in the circuit is controlled so that it is low only when the potential in the mentioned Point falls below a second predetermined value which is lower than the first mentioned value. The tube circuit can contain relay contacts, for example, which are closed only when the potential in the control point is lower than the second lower predetermined one Value.

The impedance of the tube circuit associated with the capacitor, can also be controlled in accordance with the potential of a point, which is influenced by the transmitted signals o Circuit existing tube or the tubes existing in this circuit have flowed through. In this case it is the impedance of the tube circuit is only low when the potential is in the selected Point exceeds a predetermined value. As a measure for this predetermined value, for example the strength of the weakest expected signals can be selected. With a certain Embodiment of the invention, the tube circuit includes relay contacts that only are then closed when the potential in the point in question is greater than the level of the weakest of the expected signals.

The contacts of the two relays can be in series with each other in a common Tubular circuit, and between the two relays such a mutual Connection exist that when the first mentioned relay responds, because the Potential at a point in front of the tubes has the second low predetermined value exceeds, the second relay is prevented from closing its contacts.

With such an arrangement, if the voltage of the signals at a point in one of the circuits behind the tubes exceeds the normal level, becomes the capacitor and thus a voltage is also applied to the control electrodes of the tubes. The impedances of the tubes and the attenuation in the circuit that connects the tubes in series are increased and the attenuation in the circuit containing the tubes connected in parallel is reduced.

When the potential at the point in question assumes a value that is below normal but not as low as a second lower im predetermined value, the capacitor will keep its charge, and the state the circuits does not change. But if the potential falls in the point in question below the lower limit value, one of the mentioned relays closes a tube circuit for the capacitor, which restores the circuit to its original state will. But at this point in time there will be no signals about the one mentioned by the Arrangement, the second relay is released, whereby the contacts of the same open and the discharge of the capacitor is prevented. It is thus prevented that the apparatus comes into operation without necessity if there are short interruptions arise in conversation.

An embodiment of the invention is shown schematically in the accompanying drawing shown. ·

The figure shows the invention in the form of a two-way signal transmission system, which can form a section of a long two-way transmission system.

According to the figure, wires 1 and 2 form a two-wire system, which is connected to a Four-wire system is connected, which includes a transmission path 3 and a reception path 4. The transmission path comprises a three-electrode amplifier tube S, a tube equalizing device 6 and two amplifier tubes 7 and 8. The device 6 has two three-electrode tubes 9 and 10, whose Anode circuits are connected in push-pull. A transformer 11 connected to the the two-wire circuit containing conductors 1 and 2 is connected via a potentiometer 12 connected to the input circuit of the amplifier tube 5.

The tubes 9 and 10 are with the amplifier tube 5 through a transformer 13 connected, its primary winding 14 in the output circuit of the amplifier tube 5 lies. The transformer also has two secondary windings 15 and 16. Between the ends of these secondary windings are resistors 17 and 18, their impedance in comparison with the impedance of the tubes 9 and 10 is relatively low. The anode circuits of the tubes 9 and io, the secondary windings 15 and 16 as well the shunt resistors 17 and 18 of these

Windings included are connected to the input circuit by means of a transformer 19 the amplifier tube 7 connected. A resistance element 20, its value in comparison with the impedance of the tubes 9 and 10 is low and approximately equal to the sum of the Impedances of resistors 17 and 18 is across the primary winding of the transformer 19 laid. The battery that the anode circuits of tubes 9 and 10 with Power is connected to the common cathode junction of these tubes and is also available via a resistor with an adjustable tap on the Resistor 20 in connection. The amplifier tube 7 is connected to the amplifier tube 8 via a transformer 21, and the output circuit of the amplifier S is connected to a transformer 22.

The received stream 4 contains two transformers 23 and 24 for stepping up the tension. A tube compensation device 27 is arranged between the transformer 24 and the transformers 25, 26, which includes two three-electrode tubes 28 and 29. The anode-cathode circuits the tubes 28 and 29 are connected in series with each other via the receiving path.

The anodes of the tubes 28 and 29 are directly connected to the conductors of the receiving current \ veges connected, and the cathodes of the tubes are connected to the via an inductance 30 Heads of the reception path in connection.

Between the primary winding of the transformer 25 and the inductance 30 are resistors 31 and 32 arranged while between the secondary winding of the transformer 24 and the impedance tubes 28 and 29, resistance elements 33 and 34 are provided. The impedance of the resistance elements 31 to 34 is quite high compared to the impedance of tubes 28 and 29. the Transformers 25 and 26 are used to step down the voltage, the same thing The same transformation ratio as the transformers have 23 and 24. The transformer 26 is connected to conductors 1 and 2 of the two-wire circuit in FIG Link.

A capacitor 35 controls the charge of the grids connected to the transmission path Tubes 9 and 10 and the tubes 28 and 29 connected to the receiving path. If a negative potential is applied to the grids of the tubes 9 and 10, the Attenuation in the transmission path. But if a negative potential becomes the grids of the tubes 28 and 29 pressed, the attenuation in the receiving path decreases. The voltage of the capacitor 35 is from the output circuit of the tube 8 in the transmission path by means of a Controlled circuit containing the tubes 36, 37, 38 and 39. The input circuit The amplifier tube 39 is connected to a potentiometer 40 in the output circuit of the amplifier tube 8 connected. The output circuit of the tube 39 is through a transformer 41 connected to the rectifier tube 38. The output circuit of the Tube 38 is in turn connected to amplifier tube 37 via a coupling resistor 42. The output circuit of the tube 37 is connected to the amplifier tube 36 via a coupling resistor 43, whose output circuit is connected directly to the capacitor 35.

When the peaks of the speech current in the output circuit of the amplifier tube 8 lie below an upper limit value, the grid of the rectifier tube 38 is by means of a battery 44 held strongly negative. This ensures that the tension between the grid and the filament of the tube 37 is approximately zero. By however, a considerable current flows through the amplifier tube 37 and the resistor 43. By the potential drop across part of resistor 43 becomes that of the grid of tube 38 Pressed negative potential increases. The connection between the resistor 43 and the grid of the tube 38 is made on a conductor 45. The voltage drop Via resistor 43 also contributes to making the grid of amplifier tube 36 highly negative to hold, so that in the output circuit of the tube 36 no charging current for the capacitor 35 flows.

When the peaks of the speech current in the output circuit of the amplifier tube 8 rise above the upper limit value, the negative potential of the grid of the amplifier tube 38 decreased. Resistance 42 is relatively large, and if the same of a weak current flowing through it will cause a considerable change in the Output energy of the amplifier tube 37 and the current flow in the resistor 43 will. In this way, a strong and sudden change becomes no caused in the potential between the grid and the filament of the Amplifier tube 36 is pushed open.

The charging current supplied by the output terminals of the amplifier tube 36 for the capacitor 35 flows only as long as the energy in the output circuit of the tube 8 is above the upper limit. Once the peaks of the speech wave below the upper limit drop, the charging of the capacitor 35 is interrupted. But the capacitor retains its charge,

and if another peak of the speech waves in front of the amplifier 8 the upper If the limit value is exceeded, the capacitor 35 receives an additional charge. When the tips the speech waves before the amplifier 8 fall below the upper limit value, retains the capacitor its charge, because when this energy reduction in front of the amplifier 8 arises, the potential falls over ίο the resistor 42 down to zero, while the potential across resistor 43 increases and supplies the grid of tube 36 with a high negative potential. If that Grid of the amplifier tube 36 receives a high negative potential, the impedance decreases in the charging circuit of the capacitor 35 a very high value. The ones described above Circuits can be set so that the capacitor 35 extreme discharged so slowly and that even after a period of 5 minutes the charge will be discharged Avenig changed.

The capacitor 35 is with the help a control relay 48, which is provided with an armature 49. Here the relay 48 is supported by an auxiliary relay 50, the armature of which is denoted by 51 is. The relay 48 is controlled by the output side of the amplifier tube 5, which is im Transmit current path 3 is in front of the impedance tubes 9 and 10. The auxiliary relay 50 is of the Voltage drop across part of resistor 40 or across the entire resistor 40 controlled, which is in the output circuit of the amplifier tube 8 in the transmission current path. In the released position, the armature 51 of the relay 50 is under tension and lies against the contact part 52. When the relay 50 is actuated, the armature 51 is against the contact part 53 is pressed. The armature 49 of the relay 48 receives bias and sets against the holding part 54 when the relay is released. When relay 48 is actuated armature 49 is pressed against contact 55.

A resistor 56 in the output circuit of the amplifier tube 5 is connected to the input circuit an amplifier tube 57 in connection. The output circuit of the Amplifier tube 57 is connected to the input circuit via a transformer 58 Amplifier tube 59 connected. The output circuit of the tube 59 is via a Transformer 60 connected to the input circuit of a detector tube 61, whose Output circuit is connected to the control relay 48.

When the peaks of the speech currents in the output circuit of the amplifier tube are higher than the peaks of the speech current waves generated by a participant with very result from a weak voice, the amplifier tubes 57, 59 and the detector tube 61 supply Current for the actuation of the control relay 48. A capacitor 62 with a parallel resistor 63 is arranged in the input circuit of the amplifier tube 57 and is charged by a battery 64 when the auxiliary relay 50 is excited. This creates a negative potential for the grid of the amplifier tube 57 pressed and the release of the control relay 48 secured.

The auxiliary relay 50 is from the resistor 40 in the transmission path by means of an amplifier tube 65 and a detector tube 66 actuated. The auxiliary relay 50 comes into operation when the Peaks of the speech current in the output circuit of the amplifier tube 8 are above a lower limit. When the auxiliary relay 50 is in the rest position is when the control relay 48 is in its working position, the capacitor 35 discharged through a resistor 67.

Assuming that the control relay 48 and the auxiliary relay 50 are in the position shown in the figure and a conversation is taking place over the transmission system, the relay 48 will come into action as soon as the speech currents in the output circuit of the amplifier tube 5 exceed the g ₀ peaks of the speech currents rising from a participant with a weak voice. The fact that the grid of the rectifier tube 38 is impressed with a high negative potential prevents the capacitor from being charged before the peaks of the speech currents in the output circuit of the tube 8 have exceeded the upper limit value. If the peaks of the speech currents in the output circuit of the tube 8 exceed the lower limit value, the auxiliary relay 50 responds, whereby the capacitor 62 connected to the tube 57 is charged.

The arrangement remains in this state. when the peaks of the speech currents in the output circuit of the tube 8 remain between the upper and lower limit values. As soon as the peaks of the speech currents in the output _{circuit of the tube 8 exceed the upper n 0} limit value, the amplifier tubes 36, 37, 38 and 39 apply a charge to the capacitor. Negative potential is fed from the capacitor to the grids of the impedance tubes 9 and 10 in the transmission path and to the grids of the impedance tubes 28 and 29 in the receive path. The fact that a negative voltage is fed to the grids 9 and 10 in the transmission path increases the attenuation in the transmission path. However, the negative potential impressed on the grids of the tubes 28 and 29 in the receiving path has the effect

a reduction in attenuation in the receive path.

As often as the peaks of the speech frequency currents in the output circuit of the tube 8 fall below the upper limit value, the charging of the capacitor 35 is interrupted. However, an immediate and substantial discharge only occurs when the peaks of the speech frequency currents are

to the output circuit of the amplifier tube 8 fall below the lower limit value. If the peaks of the speech frequency currents in the output circuits of the tube 5 in the transmission path are above the peaks of the speech currents originating from a quietly speaking participant, which actuate the control relay 48, and if the peaks of the speech currents in the output circuit of the tube 8 fall below the lower limit value, then there is the auxiliary relay 50 in the rest position when the control relay is in the working position. The capacitor 35 is then discharged via the resistor 67 , as a result of which the impedance in the transmission path is reduced and the impedance in the reception path is increased.

If the conversation is interrupted for a short time, the capacitor 62 depresses strong negative potential on the grid of the tube 57 which controls the relay 48. Through this, that the capacitor 62 is discharged, it is achieved that the control relay 48 quickly is triggered and works slowly. The control relay 48 is therefore before the auxiliary relay 50 released, and the setting of the control circuits for the speech strength remains therefore unchanged if the conversation is resumed immediately.

Claims (11)

Patent claims: i. Two-way transmission system, in particular telephone system, which is equipped in both circuits with compensating tube circuits which are controlled jointly as a function of the potential of a point in one of the two circuits, characterized in that one compensating tube circuit is in series with one circuit and the second compensating tube circuit is parallel is connected to the second circuit so that the attenuation increases in one circuit while it decreases in the second circuit.
2. Transmission system according to claim 1, characterized in that each compensating tube circuit contains two tubes whose anode-cathode lines are connected in push-pull and whose cathodes are connected to one another. 3. Transmission system according to claim 1 or 2, characterized in that the Point whose potential controls the circuits and whose potential controls the transmitted ones Signals is controlled, is selected behind the compensation circuits assigned to the circuit in question. 4. Transmission system according to claim 1 to 3, characterized in that the Control electrodes of all tubes of the equalization circuits connected to one another and are also connected to a capacitor (35), whose potential is controlled by the voltage at a particular point in one of the circuits. 5. Transmission system according to claim 4, characterized by a limitation Current relay device, such as a biased amplifier tube (38) between the point in the circuit whose potential controls the tubes and the capacitor (35) is so that the potential of the capacitor only changes across the circuit when the voltage in the mentioned point exceeds a predetermined value. 6. Transmission system according to claim 4 or 5, characterized by a discharge circuit for the capacitor 9c (35) j its impedance in accordance is controlled with the voltage at the point mentioned so that it is low only when the voltage in said point below a second predetermined value which is lower than the first mentioned limit value. 7. Transmission system according to claim 6, characterized in that the discharge circuit Contains contacts (51, 52) of a relay (50) that are only closed when the voltage at the mentioned point is lower than the mentioned second low one in advance Value. 8. Transmission system according to claim 4, 5, 6 or 7, characterized by a Discharge circuit for the capacitor (35) whose impedance depends on the voltage at one point in the circuit is controlled, which is controlled by the transmitted signals or the like. Before this have passed the tube or tubes associated with this circuit, so that the impedance is only low when the Voltage in the mentioned point has a predetermined value, for example exceeds the value of the weakest expected signals. 9. Transmission system according to claim 8, characterized in that the contacts (49> 55) of the discharge circuit of a Relay (48) will only be closed when the voltage in the point mentioned has reached the value specified in advance exceeds. 10. Transmission system according to claim 7 and 9, characterized in that; that the contacts (51, 52 and 49, 55 ) of the two relays (50, 48) are in series with one another in a single capacitor discharge circuit. 11. Transmission system according to claim 7, 9 or 10, characterized in that the relays (50 and 48) with each other connected, that the second relay (48) cannot come into action and its contacts (49, 55) can close when the first relay (50) is in action occurs because the tension occurs at one point in front of the tube or tubes the second exceeds the lower predetermined value. For this purpose ι sheet of drawings