SU553950A3 - Device for two-way communication - Google Patents

Description

one

The invention relates to a communication technique that can be used in a circuit to automatically activate a transit call, which serves to prevent two-way communication between two points.

A device for two-way communication is known, comprising two identical channels, each of which is designed as a series-connected electroacoustic converter, a preamplifier and a control unit connected to the inputs of the input and output switches; the output switch of the first channel is connected to the electro-acoustic converter of the second channel, the output switch of which is connected to the electro-acoustic converter of the first channel 1.

In this device, a controlled conversation is conducted in two directions and it is possible to turn on the channel at a higher volume and, thus, change the direction of the conversation, i.e., the voice enters through the conversation into that channel which corresponds to a higher sound intensity. However, on the receiving side, the conversation may be terminated by external noise or reflections. In addition, when communicating in two directions, due to strong acoustic feedback, there is a danger of self-excitation of the system.

The purpose of the invention is the elimination of acoustic feedback.

For this purpose, in the device for two-way communication, we have two identical channels, each of which is designed as a series-connected electroacoustic converter, a preamplifier and a control unit connected to the inputs of the input and output switches, and the output switch of the nerve channel is connected to the electroacoustic a second channel converter, the output switch of which is connected to the electroacoustic nerve channel converter, an amplifier-limiting amplifier is inserted into each channel An additional amplifier, a blocking node, and a power amplifier, the output of the preamplifier through the amplifier-limiter, the input switch, the power amplifier is connected to the corresponding input of the output switch, the output of the nerve canal control unit is connected to to the second inputs of the amplifier-limiter and the control unit of the second channel through an additional amplifier and blocking node, and the output of the control unit of the second channel is connected to the second inputs of the amplifier-limiter of the block systematic way of the first channel via a further amplifier and lock assembly.

The input switch of each channel is made of two transistors, the emitter and collector of which are connected to the corresponding sources, the collector of the first transistor is connected to the emitter of the second, and the bases of the obon of the transistors are connected to the common busbar and to the terminal of the transistor by the switch; the emitter of the second transistor is connected through a resistor to the base of the first transistor, the emitter of which is connected to the input terminal of the switch through a coupling capacitor, and the common point of the transistors is connected to the output terminal of the switch via another coupling capacitor.

The output switch of each channel is made of two transistors, the collector and emitter of which are interconnected and connected respectively to the output and input terminals of the switch; the base of each transistor is connected to the common bus through appropriate resistors and diodes, and to another power source through the first voltage divider a switch-control switch is connected to which the second voltage divider is connected via a phase-inversion node connected to the first power source .

FIG. 1 shows a structural electrical circuit for a two-way communication device; in fig. 2 - electrical circuit diagram of the input switch; in fig.

3 is the electrical circuit diagram of the output switch.

The device for two-way communication contains (see Fig. 1) two identical channels, each of which is designed as a series-connected electroacoustic transducer 1, preamplifier 2 and control unit 3 connected to the inputs of the input and output switches

4 and 5; the output switch 5 of the first channel is connected to the electro-acoustic converter 1 of the second channel, the output switch 5 of which is connected to the electro-acoustic converter 1 of the first channel. In each channel, the output of the preamplifier 2 through the limiting amplifier 6, the input switch 4, the power amplifier 7 is connected to the corresponding input of the output switch 5; the output of the control unit 3 of the first channel is connected to the second inputs of the amplifier-limiter 6 and the control unit 3 of the second channel through an additional amplifier 8 and blocking node 9, and the output of the control unit 3 of the second channel is connected to the second inputs of the amplifier-limiter b and control unit 3 of the first channel through an additional amplifier 8 and blocking node 9.

The input switch 4 of each channel is made (see Fig. 2) on two transistors 10, 11, the emitter and collector of which are connected to power sources 12, 13, the collector of transistor 10 being connected to the emitter of transistor 11, and the bases of both transistors through current-carrying resistors 14 , 15 and the delay circuit, consisting of a capacitor 16 and a resistor 17, are connected to the bus and to the terminal 18 of the control with a switch; at the same time, the emitter of the transistor 11 is connected through a resistor 19 to the base of the transistor 10, the emitter of which is connected to the input terminal 21 of the switch through the coupling capacitor 20; The common point of the transistors is connected through a coupling capacitor 22 to the output terminal 23 of the switch and through a resistor 24 to the busbar. A resistor 25 is connected between the emitter of the transistor 10 and the power source 12, the base of the transistor 11 is connected via a resistor 26 to the power source 12.

The output switch 5 of each channel is made (see Fig. 3) on two transistors

27, 28, the collector and emitter of which are interconnected and connected respectively to the output and input terminals 29 and 30 of the switch; In this case, the base of each transistor is connected via the corresponding resistors 31, 32 and diodes 33, 34 to the common bus, and to the other power source 35 via the first voltage divider of the resistors 36, 37 the control terminal 38 of the switch to which the second divider is connected

lines of resistors 39, 40 through a phase-inversion node consisting of a resistor 41, a transistor 42 and a diode 43 connected to the first power source 12. The device operates as follows.

If the side connected to the first channel is spoken, in the first channel the electroacoustic converter 1 works as a microphone, and the electrical signal generated by it is amplified by a preliminary

usnlitel 2. In this case, the output switch 5 is open. From the preamplifier 2, the talk signal goes to the control unit 3 and the amplifier-limiter 6. When the talk signal is applied to

the input of the control unit 3 at its output appears a constant voltage opening the input and output switches 4 and 5, then the conversational signal from the amplifier-limiter 6 comes through the input switch 4, the power amplifier 7 and the output switch 5 to the electroacoustic converter 1 of the second channel, which while working as a loudspeaker.

From the control unit 3 of the first channel, the DC voltage goes to the second channel to the blocking unit 9, which, acting on the control unit 3, prevents the switches 4 and 5 from being switched to the conducting state regardless of the value

the input signal of the control unit 3. Thus, if one channel is active, the other is securely locked, so that from the overloaded, in case of a large amount of conversational signal, the pre-amplifier 2, the signal is fed only to the input of the gain amplifier 6. Thus The danger of self-excitation when the device is operated in two directions. The blocking node 9 of the second channel is performed in such a way that the last time remains in the closed state after interrupting the conversation on the first channel, which prevents the second channel from turning on when transients arise from a brief interruption of the conversation.

The large signal at the input of the electroacoustic converter 1 in the second channel through the preamplifier 2 overloads the limiter 6, the gain of which in this case drops and is restored only after some time. Therefore, if the listener wants to immediately respond after the termination of a conversation on the first channel, the beginning of the answer is not heard or is perceived very quietly. To eliminate this phenomenon, an additional amplifier 8 is used, which is switched on for a short time by means of a pulse obtained by differentiating the voltage jump that occurs at the output of control unit 3 when it is turned off, and restores the gain of amplifier limiter 6.

Input switch 4 (see Fig. 2) works as follows.

If the switch is open, transistor 10 is conductive, transistor 11 is locked. At this point in time, the DC voltage of the collector of the transistor 10 is determined by a voltage divider formed by resistors 25, 24. If the switch is closed, the transistor 10 is locked and the voltage on its collector is determined by the voltage of the power supply 13 25, 24 and the supply voltage of the power source 13 is chosen in such a way that in both states the voltage on the collector of the transistor 10 is the same. Resistors 14, 15 limiting the base currents of transistors 10, 11. Resistors of resistors 14, 15 must be significantly greater than the resistances of resistors 24, 25 to eliminate noise-causing voltage jumps of the power source 13 that occurs when switching the input switch 4. Resistances of resistors 14, 15 must be significantly greater than resistances of resistors 24, 25. For silent operation The input switch also serves as a circuit formed by a resistor 17 and a capacitor 16, by means of which the voltage pulse appearing at the output of the switch 4 is attenuated due to the non-simultaneous switching of transistors 10, 11.

Output switch 5 (see Fig. 3) works in the following way.

At the switch control terminal 38, there is a ground potential, the transistor 42 is open. With an appropriate choice of resistors1, 40, 40 on the base of the transistor 27, the voltage in the forward direction appears compared to the emitter. The transistor 28 is in the same position with an appropriate choice of resistances.

resistors 36, 37. The input signal, the positive half-period of which opens the transistor 27 (pn-type), negative half-transistor 28 (pnp-type), post: it goes to the output terminal 29. When transmitting high power large The base current of the Traisistor 27, 28 flows through the diodes 33, 34 to the common Shiye. If a positive control voltage of a certain magnitude appears at terminal 38, the diodes open, and a block voltage occurs at the transistor bases, and the output switch attenuates the low level signal that appears at the input. Transistor 42, resistor

41 and diode 43 form a phase inversion node. With an appropriate choice of resistors 39, 40, 36 and 37, the input and output of the output switch 5 have the potential of the earth in both an open and a closed state.

Switching switch 5 is not accompanied by a voltage surge or the appearance of a pulse at its output.

Claims (3)

1. Device for two-way communication, containing two identical channels, each of which is made in the form of series-connected electroacoustic transform. a preamplifier amplifier and a control unit connected to the inputs of the input and output switches, while the output switch of the first channel is connected to the electroacoustic converter of the second channel, the output switch of which is connected to the electroacoustic converter of the first channel, characterized in that zi, an amplifier-limiter, an additional amplifier, a blocking node and a booster amplifier are inserted into each channel. in each channel, the output of the preamplifier through the limiting amplifier, the input switch, the power amplifier is connected to the corresponding input of the output switch, and the output of the control unit of the first channel connected to the second inputs of the amplifier limiter and control unit of the second channel through an additional amplifier and blocking node, and the output of the control unit of the second channel and connected to the second inputs of the amplifier-limiter and the control unit of the first channel through an additional amplifier TI node b.chock ings. 2. The device according to claim 1, excluding that the incoming switch of the channel is made on two transistors, the emitter and the collector of which are connected to the corresponding power sources, the collector of the first transistor being connected to the emitter of the second, and the bases of both transistors through current limiting resistors and delay circuits are connected to the common busbar and to the switch control terminal, while the emitter of the second transistor is connected via a resistor to the base of the first transistor, the emitter of which is connected to the input through a coupling capacitor the common terminal of the switch, the common point of the transistors is connected to the output terminal of the switch through the other coupling capacitor. 3. The device according to claim 1, characterized in that the output switch of each channel is made of two transistors, the collector and the emitter of which are interconnected and connected respectively to the output and input terminals of the switch, and the base of each transistor is connected via corresponding resistors and diodes the common busbar, and the control terminal of the switch, to which the second voltage divider is connected via the phase-reverse node connected to the first source, is connected to the other power source through the first voltage divider m power. Sources of information taken into account during the examination: 1. Patent of England No. 1250380, cl. H 4P, 10/20/71 (prototype). J 372 Jf thirty. li 29