KR930006547Y1 - Variable if filter - Google Patents

Abstract

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Description

Broadband Variable Middle Frequency Filter Circuit of Satellite Broadcast Tuner

1 is a bandwidth variable intermediate frequency filter circuit of a conventional satellite broadcast tuner.

2 is a filtering frequency band characteristic diagram in a conventional circuit.

3 is a variable bandwidth intermediate frequency filter circuit of the satellite broadcast tuner.

4 is a filtering frequency characteristic diagram in the present circuit.

* Explanation of symbols for main parts of the drawings

10: primary side tuning stage 20: secondary side tuning stage

30: center tuning stage D ₁ , D ₂ : varactor diode

R ₁ -R ₈ : Bias resistor C ₁ , C ₇ : Coupling capacitor

C ₂ -C ₆ : Sync capacitor L ₁ -L ₃ : Sync coil

The present invention relates to a satellite broadcast tuner that can receive a large number of satellite broadcasts, and in particular, to a vastly variable intermediate frequency filter circuit of a satellite broadcast tuner capable of covering all different intermediate frequency bandwidths for each broadcast satellite. will be.

Recently, as satellite broadcasting is activated, a number of broadcasting satellites appear in Europe, and their second intermediate frequency is 479.5MHz, but each satellite has a slightly different bandwidth (for example, 16MHz, 27MHz, 32MHz, etc.). Because of this, a specific satellite broadcast receiving system can only receive the broadcast satellite.

Therefore, in order to receive multiple satellite broadcasts with one satellite broadcast receiving system, several intermediate frequency filters with different bandwidths are installed inside the satellite broadcast tuner, and the desired satellite broadcasts are switched while switching them according to the corresponding broadcasting satellites. It should be designed to receive

However, in this case, since the internal filter circuit configuration of the satellite broadcast tuner is complicated and the product cost increases, there has been a study to solve this problem.

As a result, an intermediate frequency band variable filter as shown in FIG. 1 has been proposed.

As can be seen here, the input intermediate frequency signal includes a primary side tuning stage 10 including tuning capacitors C ₂ and C ₃ , a first varistor diode D ₁ and a first tuning coil L ₁ . , Filtered by the secondary side tuning stage 20 including the tuning capacitors (C ₅ , C ₆ ), the second varactor diode (D ₂ ) and the second tuning coil (L ₃ ) to be output at an intermediate frequency of a specific bandwidth. It is composed.

The tuning frequency by the primary tuning stage 10 is in parallel with the capacitance of the first tuning coil L ₁ , the first varactor diode D ₁ , the series circuit of the tuning capacitor C ₃ and this series circuit. It is determined by the connected tuning capacitor (C ₂ ), the tuning frequency by the secondary tuning stage 20 is the capacity of the second tuning coil (L ₃ ), the second varactor diode (D ₂ ), tuning capacitor (C) ₅ ) and a tuning capacitor C ₆ connected in parallel to the series circuit. The anode side of the _first varactor diode D _{1 is provided} via bias resistors R ₂ and R ₃ . Since the circuit voltage B + is applied to the cathode side of the second varactor diode D ₂ through the bias resistor R ₄ and the second tuning coil L ₃ , the bias resistor R ₁ and the first tuning. through the coil (L ₁₎ of the first varactor to the cathode side of the die Dodd (D _1), the bias resistor to the second varactor diode (D ₂₎ via an (R _5, R ₆₎ Depending on the size of the tracking voltage (V _T) applied to the anode side is the filter band moves up corresponding to each other.

Therefore, the fixed circuit voltage B + is applied to the anode side of the first varactor diode D ₁ of the primary tuning stage 10 and the cathode side of the second varactor diode D ₂ of the secondary tuning stage 20. For example, when the tracking voltage V _T is increased, the capacitance of the _first varactor diode D ₁ is decreased and the capacitance of the second varactor diode D ₂ is increased so that the first tuning stage ( The filtering frequency band by 10) is shifted and shifted toward the higher frequency, and the filtering frequency band by the secondary side tuning stage 20 is shifted and tuned to the lower frequency.

On the contrary, when the tracking voltage V _T decreases, the capacitance of the _first varactor diode D ₁ increases and the capacitance of the second varactor diode D ₂ decreases, so that the filtering frequency band of the first tuning stage 10 is reduced. Is tuned by moving toward the lower frequency and the filtering frequency band by the secondary tuning stage 20 is tuned by moving toward the higher frequency.

That is, as shown in FIG. 2, the filtering frequency band by the primary tuning stage 10 is a, the filtering frequency band by the secondary tuning stage 20 is b, and the center frequency of the intermediate frequency band is fo. In this case, when the tracking voltage (V _T ) increases, the filtering band a moves toward a "and the filtering band b moves toward b" to widen the filtering band. Satellite broadcasting reception of intermediate frequency bandwidth (32 MHz) is enabled.

On the contrary, when the tracking voltage V _T decreases, the filtering band a moves toward the a 'side and the filtering band b moves toward the b' side to narrow the filtering band, thereby allowing satellite broadcasting reception with a narrow intermediate frequency bandwidth (16 MHz).

However, in the conventional bandwidth variable filter circuit described above, the gain (-3 dB) at the center frequency (fo) of the intermediate frequency band is increased when the tracking voltage (V _T ) is increased to receive satellite broadcasting having a large intermediate frequency bandwidth. Since noise due to deviation (see frequency band c in FIG. 2) is generated, there is a limit to bringing the intermediate frequency bandwidth wide.

The purpose of the present invention is to provide a broadband variable intermediate frequency filter circuit of a satellite broadcast tuner, which enables noise-free reception of all satellite broadcasts by solving the above problems of middle frequency bandwidth expansion.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 3, the present invention has a center tuning consisting of a third tuning coil L ₂ and a tuning capacitor C ₄ between a normal primary tuning stage 10 and a secondary tuning stage 20. Install stage 30.

The intermediate frequency signal inputted to the primary tuning stage 10 through a coupling capacitor C ₁ is a tuning capacitor C ₂ , C ₃ , a first tuning coil L ₁ , and a first varactor diode D. ₁ ) is connected to pass through the tuning frequency band determined by the capacity of the, and the variable tracking through the first tuning coil (L ₁ ) and the bias resistor (R ₁ ) on the cathode side of the _first varactor diode (D ₁ ). The voltage V _T and the anode side thereof are connected to each other so that the fixed circuit voltage B + through the bias resistors R ₂ and R ₃ is applied.

In the secondary secondary tuning stage 20, the intermediate frequency signal passing through the primary tuning stage 10 receives the tuning capacitors C ₅ and C ₆ , the second tuning coil L ₃ , and the second varactor diode D _2. Is connected through the filtering band and the coupling capacitor C ₇ determined by the capacitance of the capacitor, and the second tuning coil L ₃ and the bias resistor are connected to the cathode side of the _second varactor diode D ₂ . The fixed circuit voltage B + through R ₄ ) and the variable tracking voltage V _T through the bias resistors R ₅ and R ₆ are respectively applied to the anode side thereof.

The third tuning coil L ₂ of the center tuning stage 30 is M-coupled between the _first and second tuning coils L ₁ and L ₃ of the primary and secondary tuning stages 10 and 20 to synchronize the tuning capacitor. Configure to determine the center frequency with (C ₄ ).

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

The broadcasting satellites have slightly different intermediate frequencies depending on their usage, but the center frequency of the secondary intermediate frequency bands used by all broadcasting satellites is 479.5 MHz.

Accordingly, the center tuning stage 30 of FIG. 3 has a value of the third tuning coil L ₂ coupled to the _first and second tuning coils L ₁ and L _{3 of the first} and second tuning ends 10 and 20. By adjusting the value of the over-tuning capacitor (C ₄ ), it is designed and adjusted for the mid-frequency center frequency (fo = 479.5MHz).

On the other hand, the filtering (tuning) frequency by the primary tuning stage 10 includes the capacitance of the first tuning coil L ₁ , the second varactor diode D ₁ , the series circuit of the tuning capacitor C ₃ , and the series circuit. Is determined by a tuning capacitor C ₂ connected in parallel to the second tuning coil 20, and the filtering (tuning) frequency of the second tuning coil L ₃ and the second varactor diode D ₂ is determined by the tuning capacitor C ₂ . It is determined by the capacitance, the series circuit of the tuning capacitor (C ₅ ) and the tuning capacitor (C ₆ ) connected in parallel with the series circuit, the bias resistors R ₂ , R on the anode side of the _first varactor diode (D ₁ ). ₃ ), since the circuit voltage B + is applied to the cathode side of the varactor diode D ₂ via the bias resistor R ₄ and the second tuning coil L ₃ , respectively, the bias resistor R _1. ) and the first via a tuning coil (L ₁₎ via a first varactor diode (the cathode side, and the bias resistor of ₁ D) (R _5, R ₆₎ The filtering of an intermediate frequency band becomes wider or narrower depending on the size of the second varactor diode (D ₂₎ a tracking voltage (V _T) applied to the anode side.

That is, the fixed circuit voltage B + is applied to the anode side of the first varactor diode D ₁ of the primary tuning stage 10 and the cathode side of the second varactor diode D ₂ of the secondary tuning stage 20. For example, when the tracking voltage V _T is increased, the capacitance of the _first varactor diode D ₁ is decreased and the capacitance of the second varactor diode D ₂ is increased so that the first tuning stage ( The filtering frequency band by 10) is shifted and shifted toward the higher frequency, and the filtering frequency band by the secondary side tuning stage 20 is shifted and tuned to the lower frequency.

On the contrary, when the tracking voltage V _T decreases, the capacitance of the _first varactor diode D ₁ increases and the capacitance of the second varactor diode D ₂ decreases, so that the filtering frequency band of the first tuning stage 10 is reduced. Is tuned by moving toward the lower frequency and the filtering frequency band by the secondary tuning stage 20 is tuned by moving toward the higher frequency.

Therefore, as shown in FIG. 4, when the tracking voltage V _T is high, the filtering frequency band a by the primary tuning stage 10 is toward a ", and the filtering frequency band b by the secondary tuning stage 20 is move toward b " to widen the entire filtering band, and when the tracking voltage V _T is low, the filtering frequency band a by the primary tuning stage 10 is toward a ', and by the secondary tuning stage 20 The filtering frequency band b moves toward b 'to narrow the overall filtering band.

At this time, by the filtering frequency band d of the center tuning stage 30 centered on the intermediate frequency center frequency (fo = 479.5 MHz), the filtering frequency bands a and b Since the -3dB gain attenuation points along the separation are covered, the entire filtering frequency band e is flattened so that noise is not generated.

As described above, the present invention is to install a center tuning stage with a simple configuration in an existing intermediate frequency band variable filter circuit. Since the intermediate frequency band of all satellite broadcastings can be received without noise, the intermediate frequency for receiving satellite broadcasting As the tuning circuit is simplified, the size reduction and cost reduction effect of the satellite broadcasting tuner will appear.

Claims (1)

_First and second sides including _first and _second varactor diodes D ₁ and D ₂ and first and second ductors L ₁ and L ₃ , respectively, whose capacitance changes with a change in tracking voltage V _T. A filter circuit for varying an intermediate frequency tuning band of a satellite broadcasting signal by using tuning stages (10, 20), wherein the primary and secondary tuning stages (10, 20) between the primary and secondary tuning stages (10, 20) A third tuning coil (L ₂ ) and a tuning capacitor (C ₄ ) coupled to the _first and second tuning coils (L ₁ , L ₃ ) of M) and fixed centered on the intermediate frequency center frequency (fo). Broadband variable intermediate frequency filter circuit of the satellite broadcasting tuner, characterized in that the center tuning stage 30 is further provided having a tuned bandwidth.