KR960010377Y1 - Voice automatic converting circuit of multi system - Google Patents

Abstract

None.

Description

Voice automatic switching circuit of multi system

1 is a conventional automatic voice switching circuit diagram.

2 is a voice automatic switching circuit of the present invention.

* Explanation of symbols for main parts of the drawings

11: micom 12: switching integrated device

13 voice integrated frequency detection element 14 voice carrier signal detection unit

15: first control signal switching unit 16: second control signal switching unit

211: 6.5 MHz filter 212: 5.5 MHz filter

The present invention is a TV receiver employing an FS (Frequency Synthesis) tuning system, when the B / G and D / K signals are simultaneously received by the tuner during automatic channel tuning (auto program) without switching the system The present invention relates to a voice automatic switching circuit of a multi-system for automatically selecting and outputting a voice signal.

In the conventional automatic voice switching circuit, as shown in FIG. 1, the output terminals OT ₁ and OT ₂ of the microcomputer 1 outputting a control signal according to the broadcasting method are provided through the resistors R ₁ and R ₂ . It is connected to the control terminals P ₀ and P ₁ of the switching integrated device 2, respectively, and the output terminal of the voice intermediate frequency detection integrated device 3 is connected to the resistor R ₃ and the 6.5MHZ filter Z ₁ . The resistor R ₄ and the 5.5 MHZ filter Z ₂ were connected to the input terminals IN ₁ (IN ₂ ) of the switching integrated device 3, respectively.

In addition, in the voice intermediate frequency detection integrated device 3, the control unit 2A controls the switching unit 2B according to a control signal applied to the control terminals P ₁ and P ₁ so that the input terminal IN ₁ (IN ₂ ). And the amplifier 2C amplifies and outputs the output signal of the switching section 2B.

In the above, the microcomputer 1 outputs high potentials to the output terminals OT ₁ and OT ₂ when the received broadcast signal is PAL-B / G or SECAM-B / G, and PAL-D / K or In case of SECAM-D / K method, low potential is output to both output terminals OT ₁ and OT ₂ .

In the conventional voice automatic switching device configured as described above, when the user selects the PAL-B / G or SECAM-B / G method when the received broadcast signal is the PAL-B / G or SECAM-B / G method, the microcomputer ( 1) is output to the output terminals (OT ₁ , OT ₂ ) and outputs a fixed point to the input terminals (P ₀ ), (P ₁ ) of the switching integrated device 2, so that the control unit (2A) switching unit 2B ) So that the movable terminal is connected to the input terminal (IN ₂ ) side.

At this time, the voice intermediate frequency detection integrated device 3 outputs the received PAL-B / G or SECAM-B / G type voice intermediate frequency signal, and the voice intermediate frequency signal has a carrier frequency of 5.5 MHz. The output audio intermediate frequency signal is filtered through a resistor (R ₄ ), filtered by a 5.5MHZ filter (Z ₂ ), and then input to an input terminal (IN ₂ ) of the switching unit (2), and through the switching unit (2B). Is amplified by the amplifier 2C and output.

If the user selects the PAL-D / K or SECAM-D / K scheme when the broadcast signal is PAL-B / G or SECAM-B / G scheme, the microcomputer 1 output terminal OT ₁ . (OT ₂ ) outputs a low potential and is applied to the input terminals P ₀ and P _{1 of} the switching integrated device 2, so that the control unit 2A controls the switching unit 2B so that the movable terminal Connect to the input terminal (IN ₁ ) side.

At this time, the voice intermediate frequency detection integrated device 3 outputs the received PAL-D / K or SECAM-D / K type voice intermediate frequency signal, and this voice intermediate frequency signal has a carrier frequency of 6.5 MHz. The output audio intermediate frequency signal is passed through the resistor R ₃ , filtered by the 6.5 MHz filter Z ₁ , and then input to the input terminal IN _{1 of the} switching unit 2, and then through the switching unit 2B. Is amplified by the amplifier 2C and output.

In the conventional automatic voice switching device, the broadcast signal of the received signal is PAL-B / G or SECAM-B / G, and when a channel is automatically tuned, the user first sets the B / G mode and selects an automatic channel tuner. When commanded, both video and audio signals of the PAL-B / G or SECAM-B / G system are tuned and stored in the memory in the microcomputer 1.

If the broadcast method of the received signal is PAL-D / K or SECAM-D / K, and the user selects the D / K mode when the channel is automatically tuned, the PAL-D / K command is made. Alternatively, both video and audio signals of the SECAM-D / K system are tuned and stored in the memory in the microcomputer 1.

However, in some countries in Europe where both B / G and D / K signals are received, when the user selects B / G mode, both B / G and D / K methods are selected. The microcomputer 1 outputs the high potential to both the output terminals OT ₁ and OT ₂ to selectively output only the B / G type audio signal passing through the 5.5 MHz filter Z ₂ , and the user selects the D / When the K mode is selected, the B / G method and the D / K method are selected, but the microcomputer 1 outputs a low potential to both the output terminals OT ₁ and OT ₂ so that the 6.5 MHz filter ( Since only the D / K type audio signal passing through Z ₁ ) can be selected and output, the B / K type and D / G type signals cannot be tuned during automatic channel selection, and the receiving channel must be memorized manually. There was a problem.

The present invention has been made to solve the above-mentioned conventional problems. The present invention is to determine the presence or absence of a voice carrier signal input from a voice intermediate frequency detection integrated device to a switching integrated device, and to determine the presence or absence of the determined voice carrier signal. Therefore, to provide a voice automatic switching circuit of a multi-system to receive and output both the B / G and D / K voice signal by switching the control signal output to the microcomputer to the switching integrated device. The purpose thereof is described in detail with reference to the accompanying drawings of FIG.

2 is a voice automatic switching circuit diagram of the present invention, as shown here, 6.5 MHz and 5.5 MHz output from the microcomputer 11 for outputting a control signal according to the broadcasting method, and the integrated device 13 for detecting the intermediate frequency of voice. of 6.5MHz each filter filters the sound carrier signal (Z ₁₁₎ and 5.5MHz filter (Z ₁₂₎ and the 6.5MHz filter (Z ₁₁₎ and 5.5MHz filter in response to a control signal to the microcomputer 11, the output ( A switching integrated element 12 for selectively outputting an output signal of Z ₁₂ ), and capacitors C ₁₁ and C ₁₂ and diodes D for detecting the presence or absence of an audio carrier signal output by the 6.5 MHz filter Z ₁₁ . ₁₁ ) the voice carrier signal detection unit 14 and the control signal output from the microcomputer 11 are switched in accordance with the output signal of the voice carrier signal detection unit 14 and input to the switching integrated device 12. Resistor R ₁₅ , R ₁₆ (R ₁₇ , R ₁₈ ) and transistors Q _11- Q ₁₃ (Q _14- Q ₁₆ ) The first control signal switching unit 15 and the second control signal switching unit 16 are configured.

In the drawings of FIG. 2, reference numerals R ₁₁ to R ₁₄ are resistors, and B ⁺ is a power source.

The voice automatic switching circuit of the present invention configured as described above has a high potential at both the output terminal OT ₁₁ and OT ₁₂ when the user selects the B / G mode while the power supply B ⁺ is applied. And the output high potentials of the transistors Q ₁₁ and Q _{14 of} the first control signal switching unit 15 and the second control signal switching unit 16 through the resistors R ₁₁ and R ₁₂ . applied to the base because the transistor (Q ₁₁₎ (Q ₁₄₎ is completely turned on, the power source (B ') the resistance (R ₁₃₎ (R ₁₄₎ of each through output to the meter to the transistor (Q ₁₁₎ (Q ₁₄₎ do.

At this time, if the received signal is a B / G type signal and the voice intermediate frequency signal detector 13 outputs a 5.5 MHz voice carrier signal, the output voice carrier signal passes through the resistor R ₁₄ and is a 5.5 MHZ filter. The filter is filtered through Z ₁₂ and input to the input terminal IN ₁₂ of the switching integrated device 12, and the 6.5 MHz filter Z ₁₁ does not output the voice carrier signal.

Then, the voice carrier signal detection unit 14 continuously outputs a low potential, and the transistors Q ₁₂ (Q ₁₅ ) of the first control signal switching unit 15 and the second control signal switching unit 16 are driven by the output terminal low potential. ) Is on, and transistors Q ₁₃ (Q ₁₆ ) are off, so the high potential output terminal P ₁₀ of transistor Q ₁₁ (Q ₁₄ ) outputs to its emitter 12 is an input terminal P ₁₀ . Is applied to (P ₁₁ ).

Therefore, the control unit 12A of the switching integrated element 12 controls the switching element 12B according to the high potential applied to the input terminals P ₁₀ (P ₁₁ ) so that the movable terminal thereof is the input terminal IN ₁₂ side. The audio intermediate frequency signal output from the 5.5 MHz filter Z ₁₂ is output through the switching unit 12B and amplified by the amplifier 12C.

If the received signal is a D / K type signal and the voice intermediate frequency signal detector 13 outputs a 6.5 MHz voice carrier signal, the output voice carrier signal passes through a resistor R ₁₃ and a 6.5 MHz filter. The filter is filtered through Z ₁₁ and input to the input terminal IN ₁₁ of the switching integrated device 12, and the 5.5 MHz filter Z ₁₂ does not output the voice carrier signal.

Then, the voice carrier signal detector 14 inputs the voice carrier signal output from the 6.5 MHz filter Z ₁₁ through the capacitor C ₁₁ , half-wave rectifies the diode D ₁₁ , and smoothes the capacitor C ₁₂ . Since the high potential is outputted, the transistors Q ₁₂ and Q _{15 of} the first control signal switching unit 15 and the second control signal switching unit 16 are turned off and the transistors Q ₁₃ ( Q ₁₆ is turned on so that the high potential output from transistor Q ₁₁ (Q ₁₄ ) to its emitter flows to ground through transistor Q ₁₃ (Q ₁₆ ), and the input of switching integrated device 12 Low potential is applied to all of the terminals P ₁₀ and P ₁ .

Therefore, the control unit 12A of the switching integrated element 12 controls the switching element 12B according to the low potential applied to the input terminals P ₁₀ (P ₁₁ ) so that the movable terminal thereof has the input terminal IN ₁₁ side. The audio intermediate frequency signal output by the 6.5 MHz filter Z ₁₁ is amplified by the amplifier 12C and output through the switching unit 12B.

On the other hand, when the user selects the D / K mode in contrast to the above, the microcomputer 11 outputs all of the low potentials to the output terminals OT ₁₁ and OT ₁₂ , and the output low potential is the resistance R ₁₁ ( R ₁₂ ) is applied to the bases of the transistors Q ₁₁ and Q _{14 of} the first control signal switching unit 15 and the second control signal switching unit 16, so that the transistors Q ₁₁ and Q ₁₄ are both present. It is turned off and the low potential is output to the emitter of transistors Q ₁₁ and Q ₁₄ .

At this time, if the received signal is a B / G type signal and the voice intermediate frequency signal detector 13 outputs a 5.5 MHz voice carrier signal, the output voice carrier signal passes through the resistor R ₁₄ and is a 5.5 MHZ filter. The filter is filtered through Z ₁₂ and input to the input terminal IN ₁₂ of the switching integrated device 12, and the 6.5 MHz filter Z ₁₁ does not output the voice carrier signal.

Then, the voice carrier signal detection unit 14 continues to output the low potential, and the transistor Q ₁₂ and Q ₁₅ are turned on and the transistor Q ₁₃ and Q ₁₆ are turned off by the output low potential. B ⁺ ) is output to an emitter of transistors Q ₁₂ (Q ₁₅ ) and is applied to input terminals P ₁₀ (P ₁₁ ) of the switching integrated device 12.

Therefore, the control unit 12A of the switching integrated element 12 controls the switching element 12B according to the high potential applied to the input terminal P ₁₀ (P ₁ ) so that its movable terminal is the input terminal IN ₁₂ side. The audio intermediate frequency signal output from the 5.5 MHz filter Z ₁₂ is passed through the switching section 12B, and amplified by the amplifier 12C.

If the received signal is a D / K type signal and the voice intermediate frequency signal detector 13 outputs a 6.5 MHz voice carrier signal, the output voice carrier signal passes through a resistor R ₁₃ and a 6.5 MHz filter. The filter is filtered through Z ₁₁ and input to the input terminal IN ₁₁ of the switching integrated device 12, and the 5.5 MHz filter Z ₁₂ does not output the voice carrier signal.

Then, the voice carrier signal detector 14 rectifies and smoothes the voice carrier signal output by the 6.5 MHz filter Z ₁₁ to output a high potential, so that the transistors Q ₁₂ and Q ₁₅ are turned off, and the transistor Q _{13 is turned on.} Q ₁₆ is turned on, and a low potential is applied to the input terminal P ₁₀ (P ₁₁ ) of the switching integrated device 12.

Therefore, the control unit 12A of the switching integrated element 12 controls the switching element 12B according to the low potential applied to the input terminals P ₁₀ (P ₁₁ ) so that the movable terminal thereof has the input terminal IN ₁₁ side. The audio intermediate frequency signal output by the 6.5 MHz filter Z ₁₁ is amplified by the amplifier 12C and output through the switching unit 12B.

Meanwhile, although the above described example, to detect the presence or absence of a sound carrier signal to an output signal of 6.5MHz filter (Z ₁₁₎ for example, 5.5MHz filter instead of the output signal of 6.5MHz In filter (Z ₁₁₎ carrying out the subject innovation ( The presence or absence of a voice carrier signal may be determined using the output signal of Z ₁₂ and the switching operation of the first control signal switching unit 15 and the second control signal switching unit 16 may be controlled.

As described in detail above, the present invention determines whether a voice signal is output with or without a voice carrier signal when automatically tuning a channel, and automatically selects and outputs a voice signal of another broadcasting method when the voice signal is not output. By doing so, it is possible to automatically tune in and receive channels even in areas where both B / G and D / K methods are used.

Claims (3)

6.5 MHz filter (Z ₁₁ ) and 5.5 for filtering the 6.5 MHz and 5.5 MHz voice carrier signals output from the microcomputer 11 for outputting control signals and the intermediate frequency detection integrated device 13 according to the broadcasting method. MHz filter (Z ₁₂₎ and, an integrated switching device (12) for selecting the output signal of the filter 6.5MHz (Z ₁₁₎ and 5.5MHz filter (Z ₁₂₎ output in response to a control signal to the microcomputer 11. the output And a switching unit for switching the control signal output from the microcomputer 11 to the switching integrated device 12 according to the presence or absence of the voice carrier signal output from the 6.5 MHz filter Z ₁₁ . Automatic voice switching circuit of multi system. The method of claim 1, wherein the switching unit 6.5MHz filter (Z _11), the sound carrier signal detection unit 14 for detecting the presence or absence of a sound carrier signal for output, and a microcomputer 11 is a control signal for the output sound carrier signal detector And a first control signal switching unit 15 and a second control signal switching unit 16 which are switched in accordance with the output signal of (14) and input to the switching integrated device 12. Voice automatic switching circuit. 3. The voice automatic switching circuit of claim 2, wherein the voice carrier signal detection unit (14) detects the presence or absence of rectification and smoothing of the voice carrier signal output by the 6.5 MHz filter (Z ₁₁ ).