KR910003391B1 - Half duplex transceiver - Google Patents

Abstract

The circuit detects the level of receiving voice signal to control the transmitting level and receiving level so that the acoustic coupling phenomenon is avoided. The circuit includes a transmitting attenuator for selecting the input of a first or a second path by the mode control and for attenuating the output signal of the microamplifier (10) to transmit through an output terminal (90), a transmitting level detector (30) for detecting the transmission level of the attenuator, a reception level detector (40) for detecting the level of audio signal input, a reception attenuator (50) for amplifying the input audio signal by the feedback gain of a first or a second feedback path, and an attenuation controller (60) for generating control signal applied to the attenuators to control the level of transmitting and receiving signal.

Description

Half Duplex Voice Transceiver

1 is a circuit diagram according to the present invention.

2 is a transfer characteristic of the input to output of the transmit or receive signal detector of FIG.

* Explanation of symbols for main parts of the drawings

10: microphone amplifier 20: transmitter

30: Transmission level detector 40: Reception level detector

50: reception attenuator 60: attenuation controller

70: speaker amplifier

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voice transceiver circuit, and to a half duplex voice transceiver circuit capable of transmitting and transmitting a voice in a half-duplex state as a comparison of transmitted and received voice signals.

Currently, a telephone that transmits a voice signal has a caller's voice signal and a protector's full duplex voice transceiver system, and simultaneously receives and transmits a voice to each other. However, unlike a conventional telephone, a speaker telephone (speaker telephone; Spea-ker phone) that talks in a handset-free state without using a handcell cannot use the full-duplex communication method as described above. If full-duplex communication is used in speakerphone, acoustic coupling occurs because the received voice output from the speaker is re-inputted into the microphone for transmission. In order to solve the above problems of the full-duplex communication method in the speakerphone, a half-duplex voice communication method should be adopted. Conventional circuits for half-duplex communication of speakerphones are manufactured and sold exclusively for speakerphones by famous semiconductor chip makers, but the price is high, and the internal speaker amps do not obtain sufficient voice output. The amplifier has to be attached to the outside, and the peripheral circuit is complicated and at the same time not easy to repair.

Accordingly, an object of the present invention is to provide a full-duplex voice transceiver circuit for detecting and comparing levels of voice signals to be received and received, and controlling transmission and reception outputs as a result of which there is no acoustic coupling.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a circuit according to the present invention, in which an operational amplifier (hereinafter referred to as OP) 11, an amplification resistor 12, 13, a bias resistor 14, 15 and a coupling capacitor 16 ( 21) and a noise canceling capacitor 17 and 18 and an input signal switching switch 19 to invert a signal input to the resistor 12 through the capacitor 16 and the switch 19 to a predetermined gain. The input is connected in series with a microphone amplifier 10 for amplifying and outputting an OP 22, an input and a feedback amplifier 25 and a noise canceling capacitor 25 connected in parallel with the feedback amplifier 24. Transmit Attenuator (Tx), which is composed of a resistor 26 and a switch 27 connected in parallel to the amplifying resistor 23 and outputs an inverted amplified output signal with a predetermined amplification gain according to the switching of the switch 27. ATT) and a capacitor connecting the outputs of the OP 31 and the OP 22 to the inverting terminal (-) of the OP 31. Of the diodes 37 and 38 and the OP 31 connected in parallel with each other in the reverse direction and connected from the inverting input terminal (-) of the OP 31 to the output terminal. Connected in series between the diode 39 for rectifying the output and the output terminal of the diode 39 and ground, and connected in parallel with the resistors 33 and 34 for dividing the output of the diode 39. A transmission level detector 30 configured to detect a noise output level of the OP 22, and inputs and reception input terminals 100 of the OP 41 and the OP 41 to remove noise. The capacitors 45 and the resistors 42 connected therebetween and the diodes 49 and 51 and the OP connected in parallel to each other in reverse directions and connected between the inverting input terminal (-) and the output terminal of the OP 41. The output of the diode 52 is connected in series between the diode 52 rectifying the output of the 41 and the output terminal of the diode 52 and ground. A reception level detector 40 configured to detect a reception input level, comprising a resistor 43 and a voltage divider 43 and a capacitor 47 connected in parallel with the resistor 44 to remove noise; And a switch 55 connected in parallel to the noise canceling capacitor 56 and the feedback resistor 54 connected in parallel to the feedback amplifying resistors 53 and 54 and the feedback resistor 54 and switched by a predetermined control. And an output coupling capacitor (57) configured to amplify and output the received signal with a predetermined amplification gain according to the switching of the switch (Receive Attenuator; RX ATT) 50 and a comparator for outputting a comparison result of a predetermined logic by inputting and comparing the outputs of the transmitter and receiver level detectors 30 and 4 with non-inverting and inverting terminals (+) (-). 61 and a resistor 62 that pulls up the output of the comparator 61 to switch off the switch 27 of the TX ATT 20 and the switch 55 of the RX ATT 30. DJ attenuation controller 60, OP 71, input and feedback amplification resistors 72 and 73 and a capacitor 74 to remove noise in parallel with the feedback resistor RX ATT And a speaker amplifier 70 for outputting a predetermined inverted amplification output of the OP 52 of 50.

Reference numeral 80 denotes a microphone signal input terminal, 90 is a transmission signal output terminal, a terminal connected to a telephone line, 100 is a receiving terminal connected to a telephone line and inputs a received voice signal, and 110 is a speaker. It is connected to the terminal. 120 is an audio output expansion terminal. At this time, a side tone circuit is connected between the terminals 90 and 100.

2 shows transfer characteristics of the input signal to the output signal of the transmission level detector and the reception level detector of FIG. 1, with the vertical axis representing the output voltage and the horizontal axis representing the input voltage.

An operation example of the present invention will be described below with reference to the accompanying drawings. The speakerphone, not shown in the terminal 80, is now supplied with a power supply voltage VCC (VDD) to each of the circuits of FIG. 1, and an active mute of " high " When a predetermined voice signal is input from the microphone of, the voice signal is input to the inverting terminal (-) of the OP 11 through the resistor 13.

The voice signal is inverted and amplified by a predetermined gain by the peripheral circuit constant value at the OP 11 and input to the input ends of the resistors 23 and 26 of the TX ATT 20 through the coupling capacitor 21.

At this time, if it is designed as shown in Table 1-1, such as the parameters of FIG. 1, the microphone amplification outputs a gain of 34dB.

Table 1-1

As described above, the amplified output transmission audio signal is input to the inverting terminal (-) of the OP 22 through the resistor 23 and is inverted and amplified by a predetermined gain and transmitted through the output terminal 90 connected to the telephone line. Only the AC audio signal is input to the inverting terminal (-) of the OP 31 through the capacitor 35 and the resistor 32.

At this time, a part of the voice signal is amplified by the input terminal 100 connected to the telephone line through a side tone circuit (not shown) that is amplified and output to the output terminal 90. The signal input to the input terminal 100 through the side-tone circuit is input to the input resistance 53 of the half-terminal terminal (-) of the OP 52 through the coupling capacitor 48, and the capacitor 45 on one side ) And the resistor 42 are input to the inverting terminal (-) of the OP 41.

On the other hand, the output of the OP 22 is input to the inverting terminal (-) through the capacitor 35 and the current limiting resistor 32, the OP (31) is composed of a diode 37 (38) and the reference voltage (VC) The logarithmic amplifier amplifies the input AC voltage and inputs it to the anode of the diode 39.

The diode 39 rectifies the input signal so that the resistors 33 and 34 divide the rectified voltage and input the divided voltage to the non-inverting terminal (+) of the comparator 61.

In addition, the OP 41 which inputs the output of the sidetone circuit received through the capacitor 45 and the current limiting resistor 42 is input by the log amplifier configuration, which is a configuration of the diodes 49 and 51 and the reference voltage VC. The AC voltage is amplified largely and input to the anode of the diode 52.

The diode 52 is divided by the resistors 43 and 44 by rectifying and outputting the input AC signal, and is input to the inverting terminal of the comparator 61.

In this case, the transmission characteristics of the input-to-output of the transmission level detector 30 and the reception level detector 40 have the characteristics as shown in FIG. 2 by the parameters of Table 1-1.

That is, when an AC voltage is input to the inverting terminal (-), the output is represented by a DC voltage.

The change width of the DC output voltage is somewhat different depending on the AC voltage input, and in order to perform a normal function greatly affected by the value of the input coupling capacitor and the current limiting resistor, the transmission signal of the OP 22 is transmitted. And the level input to the terminal 100 should be appropriately adjusted with the current limiting resistor.

Therefore, the detection voltage of the transmission level is input to the non-inverting terminal (+) of the comparator 61, and the detection voltage of the reception level input through the side sound circuit is also input to the inverting terminal (-).

The comparator 61 for inputting the transmission level detection signal and the reception level detection signal compares the two signals and outputs a logic signal. For example, if a predetermined voice signal is output from the microphone amplifier as in the present time, and the detection voltage of the transmission level detector 30 is greater than the detection voltage of the reception level detector 40, the comparator 61 compares the two signals to provide a logic. The signal "high" is inputted to the control signals of the switches 27 and 55 of the transmission attenuator 20 and the received signal attenuator 50.

In this case, the switches 27 and 55 are “on” switched by the output of the comparator 61, so that the microphone voice amplified signal output from the OP 11 is connected to the resistor 26 and the analog switch 27. The amplification gain of the TX ATT 20 is amplified by the gain by the input resistor 26 and the feedback resistor 24 by being input to the inverting terminal (-) of the OP 22 through.

In addition, the received signal input from the line terminal 100 to the inverting terminal (-) of the OP 52 through the resistor 53 is amplified by the gain by the "on" resistance of the input resistor 53 and the switch 55. .

Accordingly, if the TX ATT 20 and the RX ATT 50 have the circuit constant values as shown in Table 1-1, the amplification gain of the TX ATT 20 is 6.8 dB and the amplification of the RX ATT 50. The gain is set to -16dB.

Therefore, the audio signal amplified and output from the OP 11 is further amplified by the TX ATT 20 and transmitted to the telephone line connection terminal 90, and the sidetone input signal input to the telephone line connection terminal 100 is RX ATT (50). Amplified with little gain and input to the OP 71 of the speaker amplifier 70.

The signal input to the inverting terminal (-) of the OP 71 is inverted and amplified by the values of the input resistor 72 and the feedback resistor 73 and output to the output terminal 110 which is a speaker connection terminal. The amplification gain of 71) is adjusted according to the change of the feedback resistor 73 and has a maximum output power of 244mW when having the circuit constant as shown in Table 1-1.

On the other hand, when the voice signal transmitted from the other side is input to the telephone line connection terminal 100 and the output of the reception level detector 40 is greater than the output of the transmission level detector 30, the transmission and reception level detectors 30 and 40 are provided. The output of the comparator 61 comparing the output of "

At this time, the switch 27 of the TX ATT 20 and the switch 55 of the RX ATT 50 are “off” switched, so that the amplification gain of the TX ATT 20 has an amplification gain of -11.4 dB. The signal is greatly attenuated, and the amplification gain of the RX ATT 50 has gain by the resistors 53 and 54, resulting in an amplification gain of 6 dB.

Therefore, when the reception level is increased, the transmission amplification gain is greatly reduced, and a predetermined amplification in the reception signal RX ATT 50 is input to the OP 71 through the coupling capacitor 57 and the resistor 72, and the OP ( 71) the input signal is amplified and input to the speaker.

Therefore, the TX ATT 20 and the RX ATT 50 set the transmission or reception mode in accordance with the input level of the transmission or reception signal, and thus half-duplex communication is performed.

As described above, the present invention is capable of eliminating communication obstacles due to acoustic coupling by controlling the transmission and reception mode to perform duplex communication by comparing the level detection of the transmitted and received voice signals with a simple circuit configuration. The speaker driving power can be obtained, thereby reducing the cost.

Claims (2)

An output terminal 90 connected to the microphone signal input terminal 80 and one telephone line for transmitting a voice signal, an input terminal 100 connected to the other telephone line for inputting a voice signal, and outputting a predetermined amplified voice signal A half-duplex voice transmission / reception circuit having a speaker terminal (110), comprising: a micro amplifier (10) for amplifying and outputting a voice signal input to the micro signal input terminal (80) with a predetermined amplification gain, and a first input having a predetermined amplification gain. A pass and a second input path having a better gain than the first input path, and by selecting mode inputs of the first and second paths by mode control in a predetermined state, amplifying the output of the micro amplifier 10 by a predetermined gain. A transmission attenuator 20 output to the output terminal 90, a transmission level detector 30 for detecting and outputting an output level of the transmission attenuator 20, and a reception input from the input terminal 100; A reception level detector 40 which detects and outputs a bell, a first feedback path having a predetermined amplification gain, and a second feedback path whose gain is lower than that of the first feedback path. 2, a reception attenuator 50 which selects a feedback path and amplifies and outputs a signal input from the input terminal 100 with a predetermined amplification gain, and detects voltages of the transmission level detector 30 and the reception level detector 40. In comparison, when the transmission level is large, the transmission mode control signal is output to select the second path and the second feedback path for the selection operation of the transmission and reception attenuators 20 and 50. Attenuation control mechanism for outputting a reception mode control signal to select a feedback path. The inverting terminal and the microphone amplifier of the operational amplifier 22 of the operational amplifier 22, wherein the transmission attenuator 20 has an inverted and non-inverted terminal and inputs a predetermined reference voltage to the non-inverted terminal. The first input path resistor 23 is connected between the output terminals of 10), and the feedback amplifier resistor 24 and the capacitor 25 are separately connected between the inverting input terminal and the output terminal, and the second input path resistor 26 and the ana are connected. The log switch 27 is connected in series and connected in parallel with the first input path resistor 23 so that the amplification path by the resistors 23 and 24 when the analog switch 27 is " off " And amplifying the input and amplifying and outputting the input with the amplification by the resistors 26 and 24 when " on ".

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