KR200218584Y1 - Oscillator circuit of tuner - Google Patents

Abstract

The present invention relates to an oscillator circuit of a tuner, and more particularly, an OMIC for generating an intermediate frequency by mixing a high frequency signal and a resonance frequency, a first resonance circuit for generating and tuning the resonance frequency, and the first In the oscillator circuit of the tuner comprising a coupling capacitor for transmitting the output signal of the resonant circuit to the OMIC, a second matching between the OMIC and the coupling capacitor to impedance match the OMIC and the first resonant circuit The resonant circuit is connected in series, and the second resonant circuit is characterized in that the resistor and the inductor are connected in parallel.

Therefore, according to the present invention configured as described above, since the parallel resonant circuit for matching impedance is connected in series to the coupling end coupling the OMIC and the oscillation circuit, the impedance change value according to the frequency change becomes almost constant and thus all frequencies There is a useful effect that the impedance becomes nearly constant over the band and the oscillation frequency is stable.

Description

Oscillator circuit of tuner {OSCILLATOR CIRCUIT OF TUNER}

The present invention relates to an oscillator circuit of a tuner, and more particularly, to an oscillator circuit of a tuner for stabilizing an oscillation frequency by matching an impedance between an amplifier stage and a tank circuit when receiving a low band channel.

The configuration of the oscillator circuit of the tuner according to the prior art will be described with reference to the illustrated drawings.

1 is a circuit diagram including a block diagram showing an oscillator circuit of a conventional tuner, and FIG. 2 is a block diagram showing a composite inductance obtained when looking at a capacitor in an OMIC according to the prior art.

3 is a graph showing a function relationship of impedance with respect to the frequency of the oscillator circuit of the tuner according to the prior art.

As shown in FIG. 1, 10 is an OMIC (Oscillator Mixer Integrated Circuit: OMIC) that is a device for mixing and amplifying the oscillation frequency, 20 is a driving power input terminal for driving the OMIC, 30 is a high frequency signal An input high frequency signal input terminal 50 is a first resonant circuit for generating an oscillation frequency, VD is a variable capacitance diode, and L ₁ is a parallel resonant circuit that is a choke coil.

In addition, 40 is an intermediate frequency output terminal outputting an intermediate frequency generated by mixing a high frequency signal input through the high frequency signal input terminal 30 and a resonance frequency generated through the first resonant circuit 50.

At this time, the OMIC for generating the intermediate frequency by mixing the first resonant circuit 50 in which the oscillation frequency is generated and the high frequency signal is connected through the coupling capacitors C ₁ and C ₂ .

An oscillation circuit of a conventional tuner having the above configuration will be described with reference to the illustrated drawings.

As illustrated in FIG. 1, in order to oscillate first, driving power must be applied to the OMIC 10 through a driving power input terminal 20.

When the high frequency signal is input through the high frequency signal input terminal 30 and the oscillation frequency tuned through the first resonant circuit 50 is input to the OMIC 10 through the coupling capacitor C1, the oscillation frequency. And the high frequency signal input to the OMIC 10 are mixed to generate an intermediate frequency signal and output through the intermediate frequency output terminal 40.

As shown in FIG. 2, the oscillation frequency generated by the first resonant circuit 50, in which the variable capacitor diode VD and the choke coil L ₁ are connected in parallel, is tuned to thereby couple the capacitor C ₁ . When provided to the OMIC 10, the synthesized impedance changes as the oscillation frequency changes, but the characteristic has an inductor (L) value.

Meanwhile, as shown in FIG. 3, when the signal component provided through the high frequency signal input terminal 30 is high frequency and low frequency, the characteristic impedance viewed through the coupling capacitor C ₂ from the OMIC 10. It can be seen that (vertZ vert) has a large difference. In other words, as frequency increases, impedance decreases, resulting in poor frequency stability.

However, in the conventional tuner oscillator circuit, when the signal frequency provided through the high frequency signal input terminal is high frequency or low frequency, the characteristic impedance seen through the coupling capacitor in the OMIC continues to decrease as the frequency increases. Impedance in the HIGH channel or the LOW channel is not matched in the OMIC and the resonant circuit, there is a problem that an abnormal oscillation phenomenon occurs.

In addition, since the impedance matching between the OMIC and the resonant circuit cannot be sufficiently realized by the coupling capacitor alone, there is another problem that the frequency characteristics are deteriorated.

Accordingly, the present invention has been made to solve the above problems, and its purpose is to match the impedance between the OMIC and the first resonant circuit to achieve stable frequency characteristics and to prevent abnormal oscillation. To provide an oscillation circuit.

1 is a circuit diagram including a block diagram showing an oscillator circuit of a conventional tuner.

Figure 2 is a block diagram showing the composite inductance obtained when looking at the capacitor in the OMIC according to the prior art

3 is a graph showing a function relationship of impedance with respect to the frequency of an oscillator circuit of a tuner according to the prior art.

4 is a circuit diagram including a block diagram showing an oscillator circuit of a tuner according to the present invention.

5 is a block diagram showing the composite inductance obtained when looking at the capacitor in the OMIC according to the present invention

6 is a graph showing a function relationship of impedance with respect to the frequency of the oscillator circuit of the tuner according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: OMIC 20: Drive power input terminal

30: high frequency signal input terminal 40: intermediate frequency output terminal

50: first resonant circuit 60: second resonant circuit

R: Resistor C ₁ , C₂: Capacitor

L, L ₁ , L₂: Choke Coil VD: Variable Capacitance Diode

The oscillator circuit of the tuner according to the present invention for achieving the above object,

OMIC for generating an intermediate frequency by mixing at least a high frequency signal and a resonant frequency, a first resonant circuit for generating and tuning the resonant frequency, and a coupling for transferring the output signal of the first resonant circuit to the OMIC It characterized by including a capacitor.

Here, the coupling capacitor is formed by connecting a second resonant circuit in series for impedance matching between the OMIC and the first resonant circuit.

Hereinafter, a preferred embodiment of the oscillator circuit of the tuner according to the present invention will be described with reference to the illustrated drawings.

Figure 4 is a circuit diagram including a block diagram showing the oscillator circuit of the tuner according to the present invention, Figure 5 is a block diagram showing a composite inductance obtained when looking at the capacitor in the OMIC according to the present invention, Figure 6 is It is a graph showing a function relationship of impedance with respect to the frequency of the tuner oscillator circuit.

At this time, as shown in Figure 4, 10 is the OMIC, 20 is a power input terminal is provided with a power source for driving the OMIC, 30 is a high frequency signal input terminal, 40 is an intermediate frequency that is a mixture of high frequency signals and oscillation frequency signal output Output stage 50 is a first resonant circuit for generating and tuning an oscillation frequency signal, 60 is a second resonant circuit newly installed for impedance matching, and C ₁ and C ₂ are couplings for coupling between the OMIC and the first resonant circuit. The capacitor, R and L _2, are elements of the second resonant circuit, VD is a variable capacitance diode, and L ₁ is an element of the first resonant circuit, which is a choke coil.

At this time, the OMIC (10), the power input terminal 20, the high frequency signal input terminal 30, the intermediate frequency output terminal 40, the first resonant circuit 50 for generating and tuning the oscillation frequency signal of the above configuration, the OMIC Since the coupling capacitors C ₁ and C ₂ for coupling between the 10 and the first resonant circuit 50 are the same as in the conventional configuration, description thereof will be omitted.

However, the present invention will be described in detail centering on the second resonant circuit having a different configuration from the prior art.

Referring to the oscillator circuit of the tuner according to the present invention made in the above configuration in detail as follows.

As shown in FIG. 4, power for driving the OMIC 10 is input through the power input unit 20, and a high frequency signal is provided through the high frequency input terminal 30.

In addition, a tuning frequency is generated in the first resonant circuit 50 including the variable capacitance diode VD and the choke coil L ₁ and input to the OMIC 10 through the coupling capacitor C ₁ .

At this time, a high frequency signal and an oscillation frequency are mixed through a mixing unit (not shown) in the OMIC 10 to generate an intermediate frequency, and the intermediate frequency is output through the intermediate frequency output terminal 40.

Meanwhile, as shown in FIG. 5, the synthesized impedance seen through the coupling capacitor C ₂ in the OMIC 10 has characteristics of an inductor.

In addition, as shown in Figure 6, the curve is a frequency characteristic graph appearing in the coupling capacitor, through which it can be seen that the synthetic impedance value is lowered as the frequency increases. 6 is a frequency characteristic curve showing an impedance change value according to frequency for a second resonance circuit in which R and L ₂ are connected in parallel. In this case, the composite impedance increases with increasing frequency. You will know.

Therefore, as shown in the curve, when the capacitors and the second resonant circuits having the frequency characteristics are connected in series to synthesize the two characteristic frequency curves, a relatively stable and constant synthesized frequency characteristic can be obtained over the entire frequency band. do.

Accordingly, in the oscillator circuit of the tuner according to the present invention, since the second resonant circuit described in detail above is connected in series to a capacitor combining the OMIC and the first resonant circuit, stable frequency characteristics are obtained over the entire frequency band. Can be.

That is, the impedance is stabilized over the low band or the high band, so that abnormal oscillation is eliminated and the oscillation frequency is stabilized.

As described above, the oscillator circuit of the tuner according to the present invention is formed by connecting a parallel resonant circuit in series to match an impedance to a coupling end coupling the OMIC and the oscillator circuit, so that the impedance change value according to the frequency change is almost The constant effect is that the impedance is nearly constant over the entire frequency band and the oscillation frequency is stable.

Claims (1)

An OMIC for generating an intermediate frequency by mixing a high frequency signal and a resonant frequency, a first resonant circuit for generating and tuning the resonant frequency, and a coupling capacitor for transferring an output signal of the first resonant circuit to the OMIC In the oscillator circuit of the tuner comprising a, A second resonant circuit is connected in series between the OMIC and the coupling capacitor to impedance match the OMIC and the first resonant circuit. The second resonant circuit, An oscillator circuit of a tuner, comprising a resistor and an inductor connected in parallel.