JPH0224304Y2 - - Google Patents

Description

[Detailed Description of the Invention] (a) Field of Industrial Application The present invention relates to an audio intermediate frequency conversion circuit for a television receiver capable of receiving television signals of multiple systems.

(b) Prior art As is well known, the frequency of intercarrier audio signals in television receivers in Japan is
It is 4.5MHz. However, the frequency of this intercarrier audio signal differs depending on the television system of each country. In countries around Europe and the Middle East, neighboring countries have adopted different television systems. For this reason, television receivers in these countries require audio signal demodulation circuits that demodulate intercarrier audio signals of different frequencies.

Figure 1 shows an intercarrier audio signal of 4.5MHz.
A schematic diagram of an example of an audio signal demodulation circuit of a television receiver capable of receiving television broadcasts of four systems of 5.5 MHz, 6.0 MHz, and 6.5 MHz is shown.

In FIG. 1, 1 is a video intermediate frequency processing circuit. This video intermediate frequency processing circuit 1 operates at 4.5MHz, 4.5MHz,
It outputs intercarrier audio signals (hereinafter referred to as SIF signals) of 5.5MHz, 6.0MHz, and 6.5MHz.

2 is an audio signal demodulation circuit. This audio signal demodulation circuit 2 has the above-mentioned 4.5MHz, 6.0MHz, and 6.5MHz.
It consists of an audio intermediate frequency conversion circuit 3 that converts the frequency of the SIF signal to 5.5MHz, and an audio signal detection circuit 4 that detects the 5.5MHz SIF signal.

This audio intermediate frequency conversion circuit 3 includes a variable frequency oscillation circuit 5 that oscillates at 1.0MHz and 0.5MHz,
It is comprised of a mixing circuit 6 that mixes the output signal of the oscillation circuit 5 and an intercarrier audio signal, and a 5.5 MHz bandpass filter 7.

The operation of the circuit shown in FIG. 1 will be explained. 4.5MHz or 6.5MHz SIF from video intermediate frequency processing circuit 1
When a signal is being output, the variable frequency oscillation circuit 5 oscillates at 1.0MHz.

After this oscillation signal and a 4.5MHz or 6.5MHz SIF signal are mixed in a mixing circuit 6, a 5.5MHz SIF signal is extracted through a 5.5MHz band filter 7. The 5.5MHz SIF signal is detected by the audio signal detection circuit 4 and outputted as an audio signal.

Also, from video intermediate frequency circuit 1, 6.0MHz SIF
When a signal is being output, the variable frequency oscillation circuit 5 oscillates at 0.5MHz and oscillates at 6.0MHz.
Converts SIF signal to 5.5MHz.

Further, when a 5.5 MHz SIF signal is output from the video intermediate frequency circuit 1, the variable frequency oscillation circuit 5 stops oscillating.

In this way, 4.5MHz, 6.0MHz, 6.5MHz SIF
By converting the signal into a 5.5MHz signal, SIF signals of different frequencies can be detected by one audio signal detection circuit 4, resulting in lower costs.

FIG. 2 shows the variable frequency oscillation circuit 5 of the above-mentioned television receiver. In Figure 2, 8 is
0.5MHz Colpittz type oscillator circuit, 9 is 1.0MHz
This is a Colpitts-type oscillation circuit.

a is the power supply voltage supply terminal of the 0.5MHz oscillation circuit 8,
b is a power supply voltage supply terminal of the 1.0MHz oscillation circuit 9.

Q ₁ and Q ₁ ′ are oscillation transistors.

In addition, the circuit elements L ₁ , L ₁ ′, which determine the oscillation frequency
Values of C ₃ , C ₃ ′, C ₄ , C ₄ ′, etc. are set according to the respective oscillation frequencies.

And when the SIF signal is 6.5MHz or 4.5MHz,
A power supply voltage is applied to the terminal b to operate the 1.0 MHz oscillation circuit 9 and output a 1.0 MHz oscillation signal from the output terminal g.

Further, when the SIF signal is 6.0MHz, a power supply voltage is applied to terminal a, operating the 0.5MHz oscillation circuit 8, and outputting a 0.5MHz oscillation signal from the output terminal g.

When the SIF signal is 5.5MHz, no power supply voltage is applied to both terminals a and b, and the oscillation circuits 8 and 9 do not oscillate.

By the way, such a variable frequency oscillation circuit 5 is
Two oscillation circuits 8 and 9 are connected in parallel, and the number of parts is large, causing high costs.

However, among the SIF signals input to the audio signal detection circuit 4 in FIG.
The signal level of the SIF signal whose frequency has been converted is
The strength of the output signal of the variable frequency oscillation circuit 5 (hereinafter referred to as
It has characteristics that are influenced by the oscillation strength (called oscillation strength). Therefore, the oscillation intensity of the variable frequency oscillation circuit 5 is
Conventionally, separate oscillation circuits were provided in order to optimize both 1.0MHz and 0.5MHz oscillation.

(b) Purpose of the invention The present invention has been made in view of the above points, and its purpose is to provide an audio signal demodulation circuit that reduces the number of parts and operates well.

(c) Structure of the invention The invention operates the variable frequency oscillation circuit 5 by applying a power supply voltage to the variable frequency oscillation circuit 5 when the received intercarrier audio signal is 4.5MHz, 6.0MHz, or 6.5MHz. Means e and the intercarrier audio signal being received is 4.5MHz, 6.5M
Hz, switching means (d) switches the oscillation frequency of the variable frequency oscillation circuit 5 from 0.5MHz to 1.0MHz by switching the value of the reactance element (L ₂ +L ₃ , L ₃ ) that determines the oscillation frequency of the variable frequency oscillation circuit 5. , Q ₃ ) and in conjunction with this switching means (d, Q ₃ ), the bias potential of the base of the oscillation amplification transistor (Q ₂ ) of the variable frequency oscillation circuit 5 is set in a direction that compensates for changes in oscillation intensity. It is characterized by comprising a means for changing (R ₇ , D ₁ ).

(E) Embodiment FIG. 3 is a circuit diagram showing an embodiment of the present invention. In FIG. 3, 5 is a Colpitts type grounded base variable frequency oscillation circuit.

e is a power supply voltage supply terminal to which power supply voltage V _B is applied when the SIF signal is 4.5MHz, 6.0MHz, or 6.5MHz, and d is a power supply voltage supply terminal to which power supply voltage V _B is applied when the SIF signal is 4.5MHz or 6.5MHz. This is a terminal for supplying power voltage.

C ₆ , C ₇ , L ₂ , L ₃ and the like are reactance elements that determine the oscillation frequency. C ₁₁ is a coupling capacitor,
Q ₂ is an oscillation amplification transistor.

_R7 is a resistor for changing the base potential of the amplification transistor ( _Q2 ) when the SIF signal is 4.5MHz or 6.5MHz.

_D1 is a switching diode, and _Q3 is a switching transistor that turns on when the SIF signal is 4.5MHz or 6.5MHz and grounds the connection point h of variable coils _L2 and _L3 at high frequency through capacitor _C8 . .

In FIG. 3, the values of capacitors C ₆ and C ₇ are 150 pF and 820 pF, respectively, the values of capacitors C ₈ , C ₉ and C ₁₀ are 0.01 μF, and the value of capacitor C ₁₁ is 22 pF.
Also, the value of the load resistance R ₁₀ is 33KΩ, the bias resistance R ₈ ,
The value of R ₉ is 47KΩ and 5.6KΩ respectively, the value of resistor R ₇ is 27K
Ω, the value of resistors R ₅ and R ₆ is 10KΩ, and the power supply voltage V _B is +
It is 12V.

The operation of the variable frequency oscillation circuit will be explained. SIF
When the signal is 5.5MHz, the variable frequency oscillation circuit 5 does not operate because no voltage is applied to terminals e and d.

When the SIF signal is 4.5MHz or 6.5MHz, terminals e and d
The power supply voltage V _B is applied to the switching transistor Q 3 , and the switching transistor Q ₃ is turned on, and the connection point h is grounded at high frequency. At this time, the coil involved in oscillation is L ₃
becomes. Also, at this time, the power supply voltage applied to the terminal d is applied to the base of the amplification transistor (Q ₂ ) via the resistor R ₇ and the diode D ₁ to change the bias potential of the base of the transistor Q ₂ .
At this time, the oscillation frequency f ₁ of the variable frequency oscillation circuit 5
can be expressed by the following formula.

Then, change the variable coil L ₃ so that f1=1MHz.
Adjust. Furthermore, when the SIF signal is 6.0 MHz, the power supply voltage V _B is applied only to the terminal e, so the switching transistor Q ₃ is in an off state. Therefore, the value of the inductance between the base and collector involved in the oscillation of the amplification transistor (Q ₂ ) is L ₃
+L ₂ .

Also, at this time, the diode D ₁ is naturally in the OFF state, and the bias potential of the base of the amplification transistor Q ₂ is a value determined by the resistors R ₈ and R ₉ . The oscillation frequency f ₂ of the variable frequency oscillation circuit 5 at this time can be expressed by the following equation.

Then, adjust the variable coil so that f ₂ = 0.5MHz.
Adjust L ₂ .

Furthermore, the oscillation strength is determined by changing the bias value of the base of the amplifying transistor _Q2 in accordance with the change in the oscillation frequency, so that the oscillation strength is made approximately the same during 1.0MHz oscillation and 0.5MHz oscillation. The relationship between the change in oscillation frequency and the oscillation intensity is determined by factors such as the amplitude and phase of the oscillation signal fed back to the amplification transistor _Q2 , and the amplitude and phase vary in a complex manner depending on the values of the circuit elements. Therefore, the relationship between the oscillation frequency and the oscillation intensity cannot be generalized, but in the circuit of this example, the oscillation frequency is changed from 0.5MHz to 1.0MHz by switching the coil _L2 by applying the power supply voltage to the terminal d. If you switch, the feedback conditions will deteriorate,
The oscillation strength will decrease. To prevent this,
By applying the power supply voltage V _B to the base of the amplification transistor Q ₂ via the resistor R ₇ and the diode D ₁ and increasing the bias value of the base to increase the oscillation intensity, the oscillation intensity changes due to the change in the oscillation frequency. is being corrected.

(f) Effects of the invention As described above, according to the invention, it is possible to switch the variable frequency oscillation circuit 5 itself on and off and the values of the reactance elements in this circuit 5 according to the frequency of the input SIF signal. Therefore, the variable frequency oscillation circuit 5 operates well depending on the frequency of the SIF signal. Furthermore, it is useful to change the base potential of the oscillation amplification transistor according to the frequency of the input SIF signal, so that the oscillation intensity of the variable frequency oscillation circuit can be optimized.

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram showing an example of an audio signal demodulation circuit of a television receiver capable of receiving television signals of multiple systems, and FIG. 2 is a circuit diagram showing an example of a conventional variable frequency oscillation circuit. FIG. 3 is a circuit diagram showing an embodiment of the present invention. 5...Variable frequency oscillation circuit, _L2 , _L3 ...Reactance element, _Q2 ...Amplification transistor.

Claims (1)

[Scope of claim for utility model registration] The frequency of the intercarrier audio signal is 4.5MHz,
This intercarrier audio signal and the signal from the variable frequency oscillation circuit 5 are combined in the audio signal demodulation circuit 2 of the television receiver that can receive television broadcasting in four formats: 5.5MHz, 6.0MHz, and 6.5MHz. A mixing circuit 6 for mixing, a 5.5MHz band filter 7 for extracting the 5.5MHz component from the signal from the mixing circuit 6, an audio signal detection circuit 4 for detecting the 5.5MHz audio signal, and the receiving interface. carrier audio signal
means e for operating the variable frequency oscillation circuit 5 by applying a power supply voltage to the variable frequency oscillation circuit 5 when the received intercarrier audio signal is 4.5MHz, 6.0MHz, and 6.5MHz;
The oscillation frequency of the variable frequency oscillation circuit 5 is changed from 0.5MHz to 1.0MHz by switching the value of the reactance element (L ₂ +L ₃ , L ₃ ) that determines the oscillation frequency of the variable frequency oscillation circuit 5 at 4.5MHz and 6.5MHz. A switching means d, Q ₃ for switching, and an oscillation amplification transistor of the variable frequency oscillation circuit 5 in conjunction with the switching means d, Q ₃ .
An audio signal demodulation circuit for a television receiver, comprising means R ₇ and D ₁ for changing the bias potential of the base of Q ₂ in a direction that compensates for changes in oscillation intensity.