KR900002152Y1 - Multi-sound receiving circuit - Google Patents

Abstract

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Description

Multi-way Voice Receiver

1 is a conventional circuit diagram.

2 is a circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

11: band pass filter 12: mixer

13: oscillation unit 14: system control unit

The present invention relates to a multi-way voice reception circuit, and in particular, by fixing the tuning frequency to the voice FM frequency of a certain system and changing the oscillation frequency of the mixer according to the system, so that all the FM voice TV audio signals can be received. It relates to a multi-way voice reception circuit.

1 is related to a conventional voice receiving circuit, and as shown therein, the composite video signal input terminal Si includes an image detector 1, a voice filter 2, a voice detector 3, and a voice amplifier. 4) The synthesized video signal detected by the image detector 1, which is connected to the speaker 5, extracts only a specific frequency component by filtering only the audio (FM) component by the voice filter 2, and outputs the same. The signal removes the voice carrier component from the voice detector 3 and extracts the pure carrier component.

In this way, the output of the voice detector 3 is amplified by the voice amplifier 4 and then output as an audible signal through the speaker 5.

However, in such a conventional circuit, only a voice of a specific broadcasting system is received, and when a plurality of voice systems are to be received, the voice filter 2 and the voice detector 3 need to be changed. There was a disadvantage that voice cannot be received.

In view of the above disadvantages, the present invention applies the mixer with different oscillation frequencies according to the system so that all FM audio television voices can be received regardless of a specific broadcasting system. If described in detail as follows.

2 is a circuit diagram of the present invention, and as shown therein, an output side of the image detector 1 folded to the image signal input terminal Si is a band composed of capacitors C1 and C2 and R1 and R2. The mixer 12 is connected to the base of the transistor Q1 through the pass filter 11, and the collector of the transistor Q1 is connected to the parallel resonant circuit of the capacitor C3 and the variable coil L1. The oscillation drive terminal A of the system control unit 14 is connected to the base of the resistor R8 and the transistor Q2 through the resistor R7, and again through the capacitor C7 to the variable coil L3 and varactor. It is connected to the diode VD1 (VD2), the system selection terminal B of the system control unit 14 is connected to the varactor diode VD1 and the ground capacitor C8, the base of the transistor Q2 is a capacitor The collector of Q2 is connected to the emitter of the transistor Q1 of the mixer 12 via a capacitor C4 and a coil L2, and The variable terminal of the variable coil L1 is connected to the varactor diode VD2 and the ground capacitor C9 of the oscillator 13 through a voice filter 2, a voice detector 3, and a resistor R9. In addition, the output side of the voice detector 3 is connected to the speaker 5 through the voice amplifier 4, and the oscillation drive terminal A and the system selector terminal B of the system controller 14 are configured. The furnace is to output different signals according to the broadcasting system, that is, in case of NTSC (4,5MHz) system, the high potential signal and constant DC power is outputted, and SECAM-B / G, PAL-B / G In case of (5.5MHz) system, low potential signal is output to oscillation drive terminal (A), and in case of PAL-1 (6.0MHz) system, high potential and constant DC power (DC2) are output, and PAL-D / In the case of a K (6.5 MHz) system, a high potential signal and a constant DC power supply DC3 are output, and the DC power supply DC1-DC3 has a relationship of DC1 < DC2 < The capacity of the diodes VD1 and VD2 is variable according to the voltage applied to the cathode thereof, that is, the capacity of the varactor diode VD1 is changed to C11-C13 as the constant DC power supply DC1-DC3 is applied. The capacities C11-C13 have a relationship of C11> C12> C13.

Referring to the effects of the present invention configured in this way in detail as follows.

First, when a signal of the NISC (4.5 MHz) system is input through the composite video signal input terminal (Si), the video signal is passed through a band pass filter (11) composed of capacitors (C1, C2) and resistors (R1, R2). Only the voice band of 4-6Mhz is passed through and the base of transistor Q1 of mixer 12 is applied. At this time, the high potential and constant DC power supply (DCI) is output from the oscillation driving terminal (A) and the system selection terminal (B) of the system control unit 14 to output the base of the transistor Q ₂ and the VAR diode (VDI). Transistor Q ₂ is turned on by the high potential signal, and the capacity of the varactor diode VDI becomes constant capacity CII by the constant DC power supply DCI. It oscillates at 10 MHz in a resonant circuit composed of VD2, capacitors C8, C9 and variable coil L3. That is, the frequency f generated at this time is Since the variable coil L3 is adjusted to generate a frequency of 10 MHz in the capacitor C11 of the varactor diode VD1, an oscillation signal of 10 MHz is generated. The 10MHz oscillation signal thus output is applied to the transistor Q2 through the coupling capacitor C7 and outputted from its collector, and then the 10MHz oscillation signal of the mixer 12 is passed through the capacitor C4 and the coil L2. It is input to the emitter of transistor Q1. Accordingly, in the transistor Q1 of the mixer 12, in order to extract the frequency difference of the frequency of the 10 MHz oscillation signal and the 4.5 MHz inputted to the base thereof, in the collector thereof, the frequency component of 5.5 MHz uses the 5.5 MHz voice filter 2. Through the voice detection unit 3 is sent out. Accordingly, the voice detector 3 always detects FM at 5.5 MHz and extracts a voice signal. If the frequency is 5.5 dB ± Δf, this component is a DC power source through the resistor R6 and the condenser C9. By varying the capacitance of the selector diode VD2 of (13), the oscillator 13 oscillates at 10 MHz ± Δf so that a signal of 5.5 MHz is always thrust from the voice detector 3, and this output signal is After being amplified by the voice amplifier 4, the speaker 5 is output as an audible signal.

In this state, when the input signal is a signal of a PAL-B / G or SECAM-B / G (5.5 MHz voice) broadcasting system, a low potential signal is output from the oscillation drive terminal A of the system controller 14 as described above. Is applied to the base of the transistor Q2, the transistor Q2 is turned off and the oscillator 13 stops the oscillation operation so that the 5.5 MHz signal of the image detector 1 passes through the band pass filter 11. The audio signal of the tuning frequency component, that is, 5.5 MHz, which is applied to the base of Q1, is filtered through the voice filter 2 and detected by the voice detector 3 to be normally output.

In the case of the PAL-1 (6.0 MHz) broadcasting system, the transistor Q2 is turned on by the high potential signal output from the oscillation drive terminal A of the system controller 14 as described above. Since the constant DC power supply DC2> DC1 increased from the selected terminal B than in the case of the NTSC system and is applied to the selector diode VD1, the selector diode VD1 has a constant capacity (C12). Since the capacitance C12 is reduced, and thus the variable coil L3 is adjusted so that a frequency of 11.5 MHz is generated at the capacitance C12 of the varistor diode VD1, an oscillation signal of 11.5 MHz is generated. Lose.

The output 11.5 MHz oscillation signal is applied to the emitter of the transistor Q1 through the coil L2 of the mixer 12, so that the 11.5 MHz oscillation signal is a 5.5 MHz signal which is the difference signal of the 6.0 MHz input signal. The mixer 12 is tuned and output at a tuning frequency of 5.5 MHz, and this output signal is applied to the speaker 5 through the voice filter 2, the voice detector 3, and the voice amplifier 4. And output as an audible signal.

At this time, the output signal of the voice detector 3 is fed back to the varactor diode VD2 through the resistor R9 of the oscillator 13 to vary the capacitance of the varactor diode VD2, thereby causing the voice detector 3 to change. ) Always output a constant frequency, that is, 5.5MHz.

On the other hand, when the signal input to the composite video signal input terminal (Si) is a PAL-D / K (6.5MHz) system as described above, the high potential output from the oscillation drive terminal (A) of the system control unit 14 as described above The transistor Q2 is turned on by the signal, and the constant DC power supply DC2 > DC1 from the system selection terminal B is output and applied to the selector diode VD1, so that the capacitance of the selector diode VD1 C13) is reduced from the capacitance C12, and thus, since the variable coil L3 is adjusted so that a frequency of 12 MHz is generated at the capacitor C13 of the selector diode VD1, an oscillation signal of 12 MHz is generated. It is done.

In this manner, the 12 MHz oscillation signal output from the oscillator 13 is applied to the transistor Q1 emitter of the mixer 12. Accordingly, in the transistor Q1 of the mixer 12, the oscillation frequency 12 MHz and the base input frequency ( In order to extract the frequency of the difference of 6.5MHz, its collector is tuned to the tuning frequency (5.5MHz), so only 5.5MHz components are always extracted and output, and this output signal is the voice filter (2) and the voice detector ( 2) and outputs to the speaker 5 through the voice amplifier 4, wherein the output signal of the voice detector 3 is fed back to the varistor diode VD2 through the resistor R9 of the oscillator 13 Since the capacity thereof is variable, the voice detector 3 always outputs a constant frequency signal.

As described in detail above, the present invention fixes the FM frequency (5.5MHz) of a single system, and changes the power generation frequency of the mixer according to the system, thereby receiving voice (FM) broadcasting of all systems. It can be effective.

Claims (1)

The output side of the image detector 1 is connected to the base of the transistor Q1, which is connected to the collector via a band pass filter 11, in which a parallel resonance circuit of a capacitor C3 and a variable coil L1 is connected to the mixer 12. The oscillation drive terminal A of the system control unit 14 is connected to the base of the transistor Q2 through the resistor R7 and to the variable coil L3 through the capacitor C7 again. The connection point is respectively connected to the system selection terminal B and the capacitor C9 of the system control unit 14 through the selector diodes VD1 and VD2 to form the oscillation unit 13, and the transistor Q2. The collector of is connected to the emitter of the transistor Q1 of the mixer 12 through the condenser C4 and the coil L2, and the variable terminal of the variable coil L1 of the mixer 12 has a voice filter (2). ), And the connection point is connected to the voice amplifier 4 through the voice detector 3 and the connection diode VD2 and the condenser are connected through the resistor R9. The audio receiving system circuit, characterized in that is configured to connect to the connection point of the (C9).