KR920008265Y1 - Circuit of auto-selecting sound system in multi tv - Google Patents

Abstract

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Description

Audio system automatic selection circuit of multiple TV

1 is a circuit diagram of the present invention.

2 is an output voltage / frequency waveform diagram of an FM detector in a circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

l 0: filtering means 12: frequency converter

20: frequency discrimination means 22: FM detector

24 tank circuit 26 buffer

30: switching means 40: resonant circuit

CF _{1 to} CF ₅ : ceramic filter

The present invention relates to a voice system automatic selection circuit, and more particularly, to a voice system automatic selection circuit that automatically selects and detects voice frequencies of a B / G system, an I system, a D / K system, and an M system.

If you look at the broadcasting system of the current Gumi region, it is broadcasted by B / G system, I system, D / T system and M system, and these systems are of 5,5MHz, 6.0MHz, 6.5MHz, 4.5MHz frequency. It is classified.

An object of the present invention is to provide a voice system automatic selection circuit for multiple TVs, which is provided to the TV so that the voice system is automatically selected so that it can be used regardless of the broadcasting system.

In order to achieve the above object, the present invention filters a plurality of voice frequencies input through an image detector through a plurality of filters, and then controls the output of each voice signal through a switching means. In the method, the plurality of voice frequencies inputted from the image detector are first filtered, and then secondly filtered by converting to a single single voice frequency, and each of the next voice frequencies of a predetermined frequency inputted from the image detector is filtered. Filtering means; Frequency discriminating means including an LC resonant circuit and an FM detector for generating a logic signal for selecting any one of the voice frequencies filtered by said filtering means based on an audio frequency signal from said image detector; The switching means for controlling the output of the voice frequency filtered through the filtering means based on an output logic level of the frequency discriminating means input through a buffer; And a resonant circuit means for generating a resonant frequency corresponding to each voice frequency output from the switching means based on the output signal of the frequency discriminating means output through the buffer.

The filtering means in the audio system automatic selection circuit of the multiple TV according to the present invention comprises a first ceramic filter for filtering a plurality of voice frequencies input from the image detector, and converting the filtered voice frequencies into a single constant voice frequency. And a second ceramic filter for re-filtering the converted single voice frequency, and a third ceramic filter for filtering the another voice frequency input from the image detector.

Further, the first ceramic filter in the filtering means of the above-described configuration is configured by connecting a plurality of filters corresponding to a plurality of voice frequencies in parallel.

In addition, the switching means in the audio system automatic selection circuit of the multi-TV according to the present invention have a pair of transistors in which each base is connected to the ground and each collector is connected to the power supply terminal in series, and the collector of each transistor is reversed to each other. It consists of a pair of diodes connected in series.

Therefore, the present invention, as described above, firstly filters a plurality of voice frequencies input from the image detector, and then converts them into a single single voice frequency to filter the second voice and filter other voice frequencies input from the image detector. And frequency discrimination means for generating a logic signal for selecting any one of the sound frequencies filtered by the filtering means based on the sound frequency signal from the image detector. It is possible to automatically switch to detect a voice system having voice frequency bands of MHz, 6.0 MHz and 6.5 MHz.

More specifically, the present invention is to select and output the audio frequency filtered by the filtering means through the switching means based on the output signal of the frequency discrimination means based on the first ceramic filter and the audio frequency output signal of the image detector from the image detector. By configuring the TV, the TV can be operated under a voice system having voice frequency bands of the aforementioned 4.5 MHz, 5.5 MHz, 6.0 MHz and 6.5 MHz.

Hereinafter, with reference to the accompanying drawings will be described the operation of the audio system automatic selection circuit of a multi-TV according to the present invention.

1 is a circuit diagram for automatically selecting a voice system of a multiple TV according to the present invention, wherein reference numeral 10 denotes a filtering means, 12 denotes a frequency converter, 20 denotes a frequency discriminating means, 22 denotes an FM detector, 24 denotes a tank circuit, 26 denotes a buffer, and 30. Are switching means, and 40 are resonant circuits, respectively.

More specifically, the present invention connects the first ceramic filters CF _{1 to} CF ₃ between the image detector and the frequency converter 12 in parallel, and filters the audio frequency of 6.0 MHz at the source end of the frequency converter 12. The second ceramic filter CF ₅ and the diode D ₂ are connected in series. On the output side of the image detector, a third ceramic filter CF ₄ and a diode D ₄ for filtering an audio frequency of 4.5 MHz are connected in series, and the cathodes of the two diodes D ₁ and D ₂ are connected in common. It is connected to a voice detector.

In addition, an FM detector 22 and a buffer 26 are connected to the output side of the image detector for selecting an audio frequency, and the output of the buffer 26 is connected to the base of the transistor TR ₁ in the switching means 30. The emitter of the transistor TR ₁ is grounded and the collector is connected to the power supply side B ⁺ and the base of the transistor TR ₂ and to the anode of the diode D ₁ to control the output of the voice signal at 4.5 MHz. do. The emitter of the transistor TR ₂ is grounded and the collector is connected to the power supply side B ⁺ , and at the same time to the anode of the diode D ₂ to control the output of a 6.0 MHz voice signal. The FM detector 22 is provided with a tank circuit 24 composed of a coil L ₂ and a capacitor C ₇ to change the audio frequency output from the image detector to a logic level. The voice detector is connected with a parallel resonant circuit 40 composed of a coil L ₁ capacitor C ₄ , a variable capacitor C ₅ , and a diode D ₃ , and the cathode of the diode D ₃ is a buffer 26. The anode is connected to the power supply terminal B + and ground respectively.

Referring to the operation of the present invention configured as described above are as follows.

First, the first ceramic filter CF ₁ , CF ₂ .CF ₃ filters the frequencies of 5.5 MHz, 6.0 MHz, and 6.5 MHz, respectively, from the audio signal output from the image detector, and supplies them from the frequency converter 12, respectively. The signal is received at 12 and outputs a voice signal having a frequency of 6.0 MHz. In addition, the second ceramic filter CF ₄ filters the voice frequency of 4.5 MHz and supplies it to the anode of the diode D ₁ through the capacitor C ₁ .

As shown in FIG. 2, the FM detector 22 uses a low-level logic when the input frequency is V ₁ or less (that is, the input frequency is 4.5 MHz or less) with the resonance frequency 5.5 MHz of the tank circuit 24 as the center frequency. Outputs the signal (M system method), and when the input frequency is V _{2 or} more (that is, when the input frequency is 5.5MHz or more), it outputs a high level logic signal (B / G, I, D / K system method). .

First, a case in which audio signals of B / G, I, and D / K systems are output from the image detector, that is, a frequency output from the image detector is not 4.5 MHz will be described.

If a frequency other than the voice frequency of 4.5 MHz, that is, 5.5 MHz, 6.0 MHz, and 6.5 MHz is output from the image detector and input to the FM detector 22, the output signal of the FM detector 22 is output as described above. Since the high level is reached, the first transistor TR ₁ connected to the output shaft of the FM detector 22 through the buffer 26 is turned on, connected to the collector of the first transistor, and simultaneously connected to the power terminal B ⁺ . The second transistor TR _{2 to} which the base is connected is turned off.

Therefore, the diodes D ₁ and D ₂ connected to the collector side of the two first and second transistors TR ₁ and TR ₂ are turned off and turned on, respectively.

On the other hand, the audio frequency output from the image detector, that is, the frequency of one of the frequencies of 5.5MHz, 6.0MHz, 6.5MHz other than 4.5MHz corresponding to the frequency of the CF ₁ , CF ₂ and CF ₃ forming the first ceramic filter Being filtered through a filter. After converting to a constant frequency (6.0MHz) through the main fruit tree converter 12, it is filtered through the second ceramic filter (CF ₅ ) is transmitted to the voice detector through the diode (C ₅ ).

On the other hand, as mentioned earlier, when an audio frequency of 5.5, 6.0, 6.5 MHz is input to the FM detector 22, the output level of this FM detector 22 is high level, and thus the buffer 26 connected to the output side thereof. ) Also becomes high level, and diode D ₃ in resonant circuit 40 connected through the buffer is reverse biased.

That is, high potential is applied to the diode D ₃ through the resistor R ₈ . Therefore, the resonant circuit 40 generates a resonant frequency corresponding to a frequency of 6.0 MHz through the resonant loop formed by the coil L ₁ and the condenser C ₄ without being affected by the variable capacitor C ₅ . Will print to Therefore, the voice detector detects the voice frequency 6.0MHz input through the diode D ₂ in the switching means 30 and outputs the voice signal accordingly.

Next, a description will be given of the case where an audio frequency of 4.5 MHz is output from the image detector.

If a voice frequency of 4.5 MHz from the image detector is input to the FM detector 22, as mentioned above, the output of the FM detector 22 has a low level (the input frequency to the FM detector 22 is shown in FIG. of the first transistor (TR ₁₎ connected to the output side of the FM detector 22 is turned off when V ₁ or less) over this, because the buffers 26, as, at the same time as connected to the collector axis of the first transistor The second transistor TR ₂ whose base is connected to the power supply terminal B + is turned on.

Therefore, the diodes D ₁ and D ₂ connected to the collector side of these two first and second transistors TR _1. TR ₂ are turned on and turned off, respectively.

Meanwhile, the voice frequency output from the image detector, that is, the voice frequency of 4.5 MHz, is filtered through the second ceramic filter CF ₄ and then transmitted to the voice detector through the capacitor C ₁ and the diode D ₁ . .

On the other hand, as already mentioned above, when an audio frequency of 4.5 MHz from the image detector is input to the FM detector 22, the output level of the FM detector 22 becomes low level, so that the buffer connected to the output shaft ( The output of 26 also becomes low level so that the diode D ₃ in the resonant circuit 40 connected through the buffer is in a conductive state. Therefore, the resonant circuit 40 generates a resonant frequency corresponding to the frequency of 4.5MHz through the resonant rope formed by the coil L ₁ , the capacitor C ₄ , and the variable capacitor C ₅ , and outputs the resonance frequency to the voice detector. . Therefore, the voice detector detects the voice frequency 4.5MHz input through the diode D ₁ in the switching means 30 and outputs the voice signal accordingly.

As described above, the audio system automatic selection circuit of the multiple TV according to the present invention first filters a plurality of voice frequencies input from an image detector, and then converts them into a single single voice frequency to perform secondary filtering and input from the image detector. Filtering means for filtering the voice frequencies, and frequency discriminating means based on the sound frequency output signal of the image detector, and switching means for switching the voice frequencies filtered by the filtering means based on the output signal of the frequency discriminating means. By adopting a means of selective output, the TV can be operated under a voice system having voice frequencies of 5.5 MHz, 6.0 MHz and 6.5 MHz as well as 4.5 MHz.

Claims (4)

A voice system automatic selection circuit of multiple TVs configured to filter a plurality of voice frequencies input through an image detector through a plurality of filters and then control output of each voice signal through a switching means, the input being from the image detector. Filtering means for firstly filtering the plurality of voice frequencies and converting them into a single constant voice frequency, and filtering another voice frequency of a constant frequency input from the image detector; Frequency discriminating means including a LC resonant circuit and an FM detector for generating a logic signal for selecting any one of the filtered voice signals from said filtering means based on the sound frequency signal from said image detector; The switching means for switching the output of the voice frequency filtered through the filtering means based on an output logic level of the frequency discriminating means input through a buffer; And a resonant circuit means for generating a resonant frequency corresponding to each voice frequency output from said switching means on the basis of an output signal of said frequency discrimination means output through said buffer. The apparatus of claim 1, wherein the filtering unit comprises: a first ceramic filter for filtering the plurality of voice frequencies input from the image detector, a frequency converter for converting the filtered voice frequencies into a single fixed voice signal; And a third ceramic filter for re-filtering the converted voice signal, and a third ceramic filter for filtering the another voice frequency input from the image detector. The audio system automatic selection circuit according to claim 2, wherein the first ceramic filter is formed by connecting a plurality of filters corresponding to the plurality of voice frequencies in parallel. 2. The switching means according to claim 1, wherein the switching means comprises a pair of transistors in which each base is connected to ground and each collector is commonly connected to a power supply terminal in series, and a pair of diodes connected in series to each other in reverse through the collectors of the respective transistors. Voice system automatic selection circuit of a multi-TV.