KR960002200Y1 - Double tunning circuit for tuner - Google Patents

Abstract

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Description

Tuner's single-sided double demodulation circuit

1 is a block diagram of an electronic tuning tuner.

2 is a circuit diagram of a conventional short-term double demodulation circuit.

3 is an alternating current (AC) equivalent circuit diagram of a conventional single stage double tuning circuit.

4 is a frequency characteristic diagram of a conventional single stage double demodulation circuit.

5 is a circuit diagram of an inter-terminal double modulation circuit of the present invention.

6 is an AC equivalent circuit diagram of the single-side double demodulation circuit of the present invention.

7 is a frequency characteristic diagram of the inter-terminal demodulation circuit of the present invention.

* Explanation of symbols for main parts of the drawings

1 antenna 2 RF amplifier

3: single-side double demodulation circuit section 4: frequency converter

5 Mixer 6 Polar Oscillator

Q1: amplifying transistor Q2: mixed transistor

C1, C5: Combined capacitors C2, C3, C4: Correction capacitor

C5: image disturbance improvement capacitor L0: peaking coil

L1: Picking coil L2, L3: Synchronizing coil

D1, D2: variable capacitance diode R1: reverse bias resistor

The present invention relates to an inter-coupled double-tuning circuit of an electronic tuning tuner. In particular, the secondary tuning circuit includes a condenser for bypassing image frequency components, thereby improving the interfering capability of the tuner. It relates to a double tuning circuit.

Referring to FIG. 1, the conventional electronic tuning tuner includes an antenna 1 for inducing an RF signal, an RF amplifier 2 for amplifying the RF signal induced by the antenna 1, and the RF amplifier ( An inter-terminal demodulation circuit section 3 for polarizing the signal amplified in 2) by the tuning voltage, a frequency converter 4 for frequency-converting the signal polarized in the inter-terminal demodulation circuit section 3, and the frequency converter 4 A mixer (5) for mixing the signal output from the local oscillation signal and outputting an intermediate frequency (IF) signal, and a local oscillator (6) for generating and supplying a local oscillation signal to the mixer (5), The operation is as follows.

The RF signal induced by the antenna 1 is amplified by the RF amplifier 2, and the inter-terminal demodulation circuit part 3 receives a tuning voltage in the signal amplified by the RF amplifier 2 according to the tuning voltage. A signal of a channel desired to be received is polarized and output, and the frequency converter 4 converts the signal output from the intermodulation demodulation circuit part 3 to the mixer 5, and the mixer 5 supplies a local oscillator 6 The IF signal is output by mixing the local oscillation signal supplied from the C1 and the signal supplied from the frequency converter 4.

In such an electronic tuning tuner, the inter-terminal double-tuning circuit section 3 is a circuit for inputting a tuning voltage and polarizing the broadcast signal of the corresponding band by using the primary and secondary tuning circuits coupled between stages. The structure of the conventional single stage double tuning circuit is shown.

Referring to FIG. 2, a conventional single-side double demodulation circuit includes a primary side coupling capacitor C1 for coupling a signal amplified by a peaking coil Ll and an amplifying transistor Ql at the end of the RF intermediate portion 2. And a primary side tuning coil L2 constituting a primary tuning circuit of the RF signal passing through the coupling capacitor C1, and a tuning circuit together with the primary side tuning coil L2, by a tuning voltage VT. A primary-side capacitance diode (Dl) and a correction capacitor (C2) having a variable capacitance value, a reverse bias resistor (Rl) for supplying a tuning voltage (VT) to the variable capacitance diode (Dl), and the primary side A coupling coil L0 for coupling with a tuning circuit, and a secondary tuning circuit of a primary RF tuning signal induced through the coupling coil L0, the capacitance of which is varied by the tuning voltage VT. The differential variable capacitor diode D2 and the correction capacitor capacitor C3 and C4, and the variable capacitor diode D2 And a secondary side tuning coil L3 constituting the secondary side tuning circuit together with the correction capacitor C3 and a signal tuned by the secondary side tuning circuit to the mixed transistor Q2 at the first stage of the frequency converter 4. It consists of a coupling capacitor (C5), the operation is as follows.

The RF signal amplified by the amplifying transistor Ql at the end of the RF amplifier 2 and outputted between the drain-peaking coil Ll is transferred to the primary side tuning circuit L2 through the primary side coupling capacitor Cl. ) Is input to Dl (C2) to achieve l-th tuning.

That is, when the tuning voltage VT is applied as the reverse bias to the primary side variable capacitance diode Dl through the reverse bias resistor Rl, the capacitance value of the variable capacitance diode Dl is converted according to the voltage value. Frequency tuning is performed at the tuning frequency f1 corresponding to the change of the LC constant value of the tuning circuit.

The signal tuned in the primary side tuning circuit is supplied to the secondary side tuning circuits D2, C3, C4 and L3 via the coupling coil L0 to perform secondary tuning.

That is, when the tuning voltage VT is applied as the reverse bias to the secondary side variable capacitance diode D2 through the reverse bias resistor R1 and the coupling coil L0, the capacitance of the variable capacitance diode D2 depends on the voltage value. The value is changed so that the frequency tuning is performed at the tuning frequency f2 corresponding to the change of the LC constant value of the secondary tuning circuit.

Thus, the signal tuned by the primary and secondary tuning circuits has a center frequency of f0 and a tuning bandwidth of f2-f1, and the tuned signal is a mixing transistor of the mixer 4 through the secondary coupling capacitor C5 ( It is supplied to Q2).

FIG. 3 shows an AC equivalent circuit diagram of the inter-terminal double tuning circuit of FIG. 2. Referring to this, it can be seen that the primary tuning frequency f1 and the secondary tuning frequency f2 are determined as follows. have.

That is, since the primary side tuning circuit and the secondary side tuning circuit constitute an LC parallel resonance circuit, the equivalent capacitance CT on the primary side is the capacitance value of the correction capacitor C2 and the capacitance value of the variable capacitance diode D1. The combined capacitance value of (C _D1 ), and the equivalent capacitance value of the secondary side C _T 'The combined capacitance value of the constant capacitance value (C _D2 ) of the compensation capacitor (C3) (C4) and the variable capacitance diode (D2) is The primary tuning frequency f1 is Becomes the secondary side tuning frequency f2, This tuning frequency characteristic is shown in Fig. 4 (middle frequency, f0).

Observing the tuning frequency characteristic of FIG. 4, there is a problem in that the image interference elimination capability is lowered by the size A of the image frequency f _image located above the tuning band at the reception of the high frequency.

The present invention solves the problems of the conventional single-step tuning circuit described above. The primary tuning circuit is an LC parallel resonant circuit, and the secondary tuning circuit is composed of a π-type tuning circuit which reduces the magnitude of the image frequency. It is an object of the present invention to provide an inter-terminal demodulation circuit of an electronic tuning tuner, which reduces image disturbance occurring when a higher frequency becomes higher, thereby improving image quality.

5 shows a configuration of an intermodulation double modulation circuit of a tuner of the present invention for achieving the above object, referring to the present invention, a peaking coil Ll and an amplifying transistor Ql at the end of the RF amplifier 2 are shown. A primary side coupling capacitor C1 for coupling with the signal amplified by the primary side, a primary side tuning coil L2 constituting a primary tuning circuit for the RF signal passing through the coupling capacitor C1, and the primary side tuning Together with the coil L2, an LC parallel tuning circuit forms a primary side capacitance diode Dl and a correction capacitor C2, the capacitance of which is varied by the tuning voltage VT, and the variable capacitance diode Dl. A reverse bias resistor Rl for supplying a tuning voltage VT, a coupling coil L0 for coupling with the primary tuning circuit, and a primary RF tuning signal induced through the coupling coil L0. A differential π-type tuning circuit is formed and the capacitance value is changed by the tuning voltage (VT). Secondary side tuning coil forming a secondary side π-type tuning circuit together with the variable secondary side variable capacitance diode D2 and the correction capacitor capacitor C3 and C4, and the variable capacitor diode D2 and the correction capacitor capacitor C3. (L3) and an image disturbance improvement capacitor (C6) that bypasses the image frequency components to remove the image disturbance, and supplies a signal tuned by the secondary side tuning circuit to the mixed transistor (Q2) at the first stage of the frequency converter (4). Composed of a coupling capacitor (C5), the operation is as follows.

The RF signal amplified by the amplifying transistor Ql at the end of the RF amplifier 2 and output between the drain-peaking coil Ll is passed through the primary side coupling capacitor C1 to the primary side tuning circuit L2. It is input to (Dl) (C2) to achieve first tuning.

That is, when the tuning voltage VT is applied as the reverse bias to the primary side variable capacitance diode D1 through the reverse bias resistor R1, the capacitance value of the variable capacitance diode Dl is changed according to the voltage value. Frequency tuning is performed at the tuning frequency f1 corresponding to the change of the LC constant value of the tuning circuit.

The signal tuned in the primary side tuning circuit is supplied to the secondary side tuning circuits D2, C3, C4, C6 and L3 through the coupling coil L0 to perform secondary tuning.

That is, when the tuning voltage VT is applied as the reverse bias to the secondary variable capacitance diode D2 through the reverse bias resistor Rl and the coupling coil L0, the capacitance of the variable capacitance diode D2 depends on the voltage value. The value is changed so that the frequency tuning is performed at the tuning frequency f2 corresponding to the change of the LC constant value of the secondary tuning circuit.

Thus, the signal tuned by the primary and secondary tuning circuits has a center frequency of f0 and a tuning bandwidth of f2-f1. The tuned signal is supplied to the mixing transistor Q2 of the mixer 4 via the secondary side coupling capacitor C5.

At this time, since the secondary-side tuning circuit constitutes the π-type tuning circuit by the tuning coil L3 and the image disturbance improving capacitor C6, the capacitor C6 for the image frequency f _image component located at the higher frequency in the tuning band. Because the impedance of s is drastically reduced, the image frequency components are bypassed and the signal level is reduced.

FIG. 6 illustrates an AC equivalent circuit of the inter-terminal double tuning circuit of FIG. 5. Referring to this, it can be seen that the primary tuning frequency fl and the secondary tuning frequency f2 are determined as follows. have.

That is, the equivalent capacitance value CT on the primary side is the combined capacitance value of the capacitance value of the correction capacitor C2 and the capacitance value CD ₁ of the variable capacitance diode D1, and the equivalent capacitance value C on the secondary side. _T 'becomes the combined capacitance value of the capacitance value C _D2 of the correction capacitor C3 and the variable capacitance diode D2, and the primary tuning frequency f1 is Becomes the secondary side tuning frequency f2, This tuning frequency characteristic is shown in FIG. 7 (middle frequency, f0).

Observing the tuning frequency characteristic of FIG. 7, when receiving a high frequency, the magnitude B of the image frequency f _image located above the tuning band is reduced by AB by the capacitor C6, thereby reducing image disturbance. It can be seen that the exclusion ability has been improved.

As described above, according to the present invention, it is possible to reduce the image frequency component appearing in the secondary side tuning circuit in the tuner's inter-terminal tuning circuit, thereby improving the ability to prevent image disturbance, There is an effect that can prevent degradation and provide a clear image of high quality.

Claims (1)

The primary side coupling coil (C1) for coupling with the RF amplifier (2) of the front end constituting the electronic tuning tuner, and the primary side tuning coil forming the primary tuning circuit of the RF signal passing through the coupling capacitor (C1) ( L2), a primary side capacitance diode (Dl) and a correction capacitor (C2) which form an LC parallel tuning circuit together with the primary side tuning coil (L2) and whose capacitance value is changed by the tuning voltage (VT); An inverse bias resistor (Rl) for supplying a tuning voltage (VT) to the variable capacitance diode (Dl), a coupling coil (L0) for coupling with the primary side tuning circuit, and induction through the coupling coil (L0) A secondary side variable capacitance diode (D2) and a correction capacitor (C3) (C4) which form a secondary π-type tuning circuit of the primary side RF tuning signal and whose capacitance is varied by the tuning voltage (VT); Secondary to form secondary side π-type tuning circuit with capacitive diode (D2) and correction capacitor (C3) An image disturbance condenser (C6) which bypasses the side tuning coil (L3) and the image frequency component to remove image disturbance, and a coupling for supplying a signal tuned by the secondary side tuning circuit to the frequency converter (4) of the rear stage. A single stage double demodulation circuit of a tuner composed of a capacitor (C5).