KR930005163Y1 - Uhf input circuit - Google Patents

Abstract

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Description

UHF input tuning circuit

1 is a conventional circuit diagram.

2 is a circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: antenna input stage 2: high pass filter

3, 10: input tuning unit 4: tuning voltage input terminal

5: AGC input 6: RF amplifier

VD ₁ , VD ₂ : First and second varactor diodes

The present invention relates to an input circuit of a UHF tuner, and more particularly, to an UHF input tuning circuit having an improved voltage standing wave ratio (VSWR) determined by a wide bandwidth of a tuning bandwidth among the input characteristics of the UHF input circuit.

Conventional electronic tuners of this type generally have an input circuit, an RF amplification circuit, a mixer circuit, and a local oscillation circuit, and have a configuration in which each circuit is combined into a short inter-tuning circuit.

Such an electronic tuner is roughly classified into a lumped constant type and a distributed integer type by a tuning method of a tuning circuit. The lumped integer type has the advantage of good mass productivity because it can be configured by using individual elements on the printed board. However, since the loss of the tuning signal and the size loss are large, it is easy to cause NF (Noise Index) deterioration especially in the input circuit. Since the 75 kHz unbalanced input impedance of the antenna is unbalanced, it has a drawback that it is very difficult to convert it to 200 to 3000 kHz balanced. In addition, the distribution constant type has a strip line type and a semi-coaxial type, and the strip line type can be configured on a printed board, which is advantageous in terms of mass productivity. However, since the antenna input impedance is unbalanced at 75 Hz, the conversion is difficult. have.

The semi-coaxial type is divided into four partitions in a metal case, and each circuit is configured in each room, and the circuits are coupled to each other by a tuning circuit using a center conductor.

This semicoaxial type has a low loss, and has the excellent advantage that the input impedance can be freely selected in terms of equilibrium, unbalance, and the like.However, due to the structural and constraints such as the center conductor being airborne, the mass production is poor. It has the drawback of being high. In the case of the lumped constant string type, a balun using a string line is often used as a 300Ω to 75Ω converter of input impedance, but in this case, it is difficult to maintain a good balance-unbalance ratio over a wide frequency, It is easy to receive interference waves such as UHF band, VHF band by data. This requires a high pass filter in the input circuit.

In addition, in the related art, as shown in FIG. ₁ , a high pass filter 2 including a capacitor C ₁ , C ₂ , and a coil L _{1 is} connected to an antenna RF input terminal 1, and The output stage of the high pass filter 2 is connected to an input tuning part 3 composed of _{first to} third tuning inductors L _{1 to} L ₃ , a capacitor C ₇ , and a first varactor diode VD ₁ . It consists. In particular, the first tuning inductor L ₁ is provided in the form of an air coil by a microstrip, and the second and third tuning inductors L ₁ and L ₃ are provided in the form of a plate inductor.

In addition, the capacitor C ₃ connected to the second tuning inductor L ₂ is provided for bypass, and the tuning voltage applied to the tuning voltage terminal 4 is supplied to the second varactor diode VD ₁ . Doing.

On the other hand, the tuning output of the input tuning section 3 is provided to the RF amplifier 6, which has an AGC input stage 5 for automatic gain control and a UHF selection power stage 7 for UHF selection. ) Is prepared. Therefore, the RF antenna signal through the high pass filter 2 is tuned in the input tuning unit 3, and since the bandwidth of the UHF input waveform is very wide, the characteristic resistance and voltage standing wave ratio due to the incidence signal are increased. Ratio is a problem.

In particular, the European tuner (arm type) must satisfy the FTZ standard, which can be solved by bringing the tuning band into a narrow band.

The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide a UHF input tuning circuit by improving the UHF input characteristics by configuring a second varactor diode in the input tuning unit of the UHF tuner. have.

The technical configuration for achieving the above object of the present invention is characterized in that the second varactor diode is installed in the plate inductor of the input tuning unit, and the varactor diode is connected to the tuning input terminal through a resistor.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a circuit diagram of the present invention, in which the UHF RF input signal coming into the antenna input stage 1 is tuned to the tuning voltage by the input tuning stage 10 through the high pass filter 2 and then in the RF amplifier 6. Configure to be amplified.

Here, the configuration of the high pass filter 2 and the RF amplifier 6 and its peripheral circuit is the same as the conventional circuit described above, and the input tuning stage provided between the high pass filter 2 and the RF amplifier 6 ( 10) has a unique circuit configuration different from the conventional circuit.

Specifically, the input tuning stage 10 tunes by inducing the UHF RF input signal appearing in the first tuning inductor L ₁ through the high pass filter 2 to the second and third tuning inductors L ₂ and L ₃ . Determine the RF input tuning band together with the combined capacitance of the first varactor diode VD ₁ and the tuning compensation capacitor C ₇ whose self capacitance varies according to the tuning voltage applied through the voltage stage 4, All of the first to third tuning inductors (L _{1 to} L ₃ ) are provided with plate inductors, and the first tuning inductor (L ₁ ) includes a second varactor diode (VD ₂ ) interlocked according to the tuning voltage. The tuning frequency band is shifted according to the tuning voltage.

Here, the resistors R ₁ and R ₂ are current limiting resistors of the tuning voltages provided to the varactor diodes VD ₁ and VD ₂ , and the capacitor C ₂ is a capacitor for signal bypass.

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

First, the RF input signal of the antenna input terminal 1 passing through the high pass filter 2 appears in the first tuning inductor L ₁ constituting the first tuning circuit between stages in the input tuning stage 10, and the first tuning The RF signal shown in the inductor L ₁ is induced in the second and third tuning inductors L ₂ and L ₃ constituting the step-by-step _secondary tuning circuit, and the capacitance value of the _first varactor diode VD ₁ and the tuning compensation capacitor ( After tuning to the tuning frequency band according to the combined capacity of C ₇ ) is output to the RF amplifier (6).

At this time, since the capacitance value of the first varactor diode VD ₁ is changed according to the tuning voltage of the tuning voltage terminal 4 applied through the resistor R ₁ , the tuning band of the input tuning stage 10 is a channel. Shifted according to selection.

In addition, a second varactor diode VD ₁ is connected in series to the first tuning inductor L ₁ to form a first tuning circuit between the stages, and the tuning voltage is applied to the _second varactor diode VD ₂ . Since the varactor diode VD ₁ is commonly applied, the first tuning band between stages of the input tuning stage 10 also changes according to the change of the channel selection tuning voltage.

Therefore, when the channel selection tuning voltage of the tuning voltage stage 4 is moved, the tuning bands of the input tuning stage 10 by the first and second tuning circuits are moved at regular intervals. Channel rejection ratio is improved.

On the other hand, the RF signal passing through the input tuning stage 10 is amplified by the RF amplifier 6 having the AGC input stage 5 and the UHF select power stage 7 via the coupling capacitor C ₆ , and then the RF output stage 8. Through the back end (mixer stage) is provided.

As described above, the present invention maintains the RF signal passband of a selected channel according to a tuning voltage in a narrow band by shifting a single inter-tuning band to a UHF input tuning circuit according to a tuning voltage, thereby reducing the section ratio of an adjacent channel signal. The effect is to be significantly improved.

Claims (1)

A first bar whose capacitance varies according to the tuning voltage by inducing the UHF RF input signal appearing on the first tuning inductor L ₁ through the high pass filter 2 to the second and third tuning inductors L ₂ and L ₃ . In an RF input tuning circuit for band-tuning together with the combined capacitances of the varactor diode (VD ₁ ) and the tuning compensation capacitor (C ₇ ), the first to third tuning inductors (L _{1 to} L ₃ ) are all provided as plate inductors The first tuning inductor (L ₁ ) is provided with a second varactor diode (VD ₂ ) interlocked in accordance with the tuning voltage UHF input tuning, characterized in that the tuning frequency band is configured to shift according to the tuning voltage in.