KR940003613Y1 - Wideband variable input filter circuit - Google Patents

Abstract

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Description

Broadband Variable Input Filter Circuit of Satellite Broadcast Tuner

1 is a conventional circuit diagram.

2 is a frequency characteristic diagram of FIG.

3 is a circuit diagram of the present invention.

4 is a frequency characteristic diagram of the present invention.

* Explanation of symbols for main parts of the drawings

10: first high frequency variable trap unit 20: second high frequency variable trap unit

30: high pass filter 40: low frequency variable trap

C ₁ -C ₆ : Capacitor D ₁ -D ₄ : Varactor diode

L ₁ -L ₆ : Inductor R ₁ -R ₄ : Resistance

The present invention relates to a wideband input filter circuit of a satellite broadcast tuner for expanding the number of receive channels of a satellite tuner, and in particular, a wideband variable input filter circuit of a satellite broadcast tuner capable of removing intermodulation and improving image characteristics when selecting a high channel. It is about.

Satellite broadcasting transmits 10.95 ㎓-12 전자 electromagnetic waves to the ground from the geostationary satellite over the equator, and transmits 1 방송 broadcast signals to the indoor satellite tuner by converting it to an outdoor low noise block converter (LNB). do.

In general, since the ECS band has a frequency band of 10.95-11.7 kHz, mixing it with an oscillation frequency of 10 kHz in a low noise block converter yields a primary conversion frequency of 950-1700 MHz.

The 950-1700 MHz primary conversion satellite broadcast signal is input to the satellite broadcast tuner and passes through an input filter set to the band. However, the satellite broadcasting tuner for receiving the European telecommunication satellite band cannot cover the European Ku band. The reason is that the European Ku band is 11.7-12.05 kHz, so the first conversion frequency is 1700-2050 MHz, so it cannot pass through the input filter of the existing ECS band. Therefore, in order to cover all satellite broadcasts, the input filter of the satellite tuner must be widened.

1 shows a broadband (950-2050 MHz, input filter circuit) of a satellite broadcasting tuner filed by the applicant of the present invention as the same as the present invention.

In this case, the LC input signal through the input coupling capacitor (C ₁ ) has a series of inductors (L ₁ -L ₃ ) and 950MHz cut-off frequency characteristics connected in series, and consists of a capacitor (C ₅ ) and an inductor (L ₄ ). The _first and second high frequency variable traps 10 are connected to each other through the high pass filter 30 and between the inductor L ₁ and the inductor L ₂ , and between the inductor L ₂ and the inductor L ₃ , respectively. 20).

The first and second high frequency trap units 10 and 20 have varactor diodes D ₁ and D ₂ and capacitance-controlled capacitors C ₃ and C ₄ whose capacitance changes depending on the size of the tuning voltage V _T. Each). In the drawing, the resistors R ₁ -R ₄ are for biasing the varactor diodes D ₁ , D ₂ , and the capacitor C ₂ is for bypassing the AC signal component with the tuning voltage V _T , and the capacitor (C ₆ ) is for output coupling.

In the input filter circuit, when the RF input signal enters the RF input filter through the coupling capacitor C ₁ , the trap frequency of the first and second high frequency variable trap units 10 and 20 depends on the size of the tuning voltage V _T. The point is moved to have a variable filtering band from the bandwidth of a (950-1600 MHz) to the bandwidth of b (950-2050 MHz) as shown in FIG.

In the RF input filtering, the high pass filter 30 cuts low frequencies below the lower limit (950 HMz) in the filtering band.

However, in the conventional circuit described above, the wideband input signal filtering of 950-2050MHz can satisfy the intermodulation characteristics and image characteristics in the passband of 950-1750MHz, but when extended to 2050MHz, A problem arises in which harmonic components interfere with high channel signals. For example, when selecting a high channel signal of 1900 MHz, a harmonic component (1900 MHz) of 950 MHz (low channel signal) acts as a disturbing wave to the high channel signal.

The present invention eliminates the phenomenon that the harmonics caused by the low channel pass frequency affect the high channel when the filtering band of the RF input filter of the satellite broadcasting tuner is expanded, thereby improving the image characteristics and intermodulation characteristics. We propose a wideband variable input filter.

The feature of the present invention is that the filtering frequency is shifted toward the high channel to exclude the high channel interference caused by the low channel frequency when the filtering band of the RF input filter is expanded. For the input filter, a certain limited width is allowed to have a passband.

Hereinafter, the present invention according to the accompanying drawings as follows.

3 is a detailed circuit diagram of the present invention, in which the RF input signal through the input coupling capacitor C ₁ is connected in series with the first to third inductors L _{1 to} L ₃ , the capacitor C ₅ , and the It is configured to be connected to the output through the LC high pass filter 30 of the 950MHz cutoff frequency characteristics consisting of four inductors (L ₄ ).

At the connection point between the input coupling capacitor C ₁ and the first inductor L ₁ , a tuning voltage V _T is provided through a bias resistor R ₁ and R ₂ and a bypass capacitor C ₂ for blocking the AC signal component. ) Is configured to be applied.

The first inductor (L ₁₎ and the second inductor connection point between the (L _2), the first varactor diode (D ₁₎ and is the first bar in series with the anode side of the varactor diode (D ₁₎ the ground A first high frequency variable trap part configured of a ratio adjusting capacitor C ₃ and determining a trap point between 1700-2050 MHz according to the magnitude of the tuning voltage V _T applied through the first inductor L ₁ ( 10) Install. The anode side of the first varactor diode D ₁ is grounded through a bias resistor R ₃ .

At the connection point between the second inductor L ₂ and the third inductor L ₃ , the third and fourth varactor diodes D ₃ and D ₄ , each of which has an anode side grounded, and these third and fourth varactor diodes (D _3, D ₄₎ is composed of a second inductor 5 and 6 (L _5, L ₆₎ respectively connected in series to the cathode side of the first and second inductors (L _1, L ₂₎ applied through the serially A low frequency variable trap unit 40 having a trap point determined between 950-1200 MHz is provided according to the size of the tuning voltage V _T.

It said third inductor (L ₃₎ and the LC are connected in series to the anode side of the high-pass filter (30) connection point, the second varactor diode (D ₂₎ and a second varactor diode (D ₂₎ between the ground Low frequency, which is composed of a proportional capacitor C ₄ , and a trap point is determined between 950-1200 MHz according to the magnitude of the tuning voltage V _T through the _{first to} third inductors L _{1 to} L ₃ in series. The variable trap part 40 is provided.

A connection point between the third inductor L ₃ and the LC high pass filter 30 is connected in series to an anode side of the second varactor diode D ₂ and the second varactor diode D ₂ . composed of a capacitor for adjusting the ratio (D ₄₎ is the point where the trapped between 1700-2050㎒ according to the magnitude of the tuning voltage (V _T) through the first-third inductor (l ₁ -L ₃₎ in series to determine A high frequency variable trap section 20 is provided.

The anode side of the second varactor diode D ₂ is grounded through a bias resistor R ₄ .

In the figure, the capacitor C ₆ is for RF output coupling, and the first to fourth inductors L _{1 to} L ₆ are formed by using a micro strip line on the circuit board.

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

In FIG. 3, the RF input signal in the 950-2050 MHz band is in principle a high frequency having an input coupling capacitor C ₁ and the first to third inductors L ₁ -L ₃ and a cutoff frequency characteristic of 950 MHz or less. It is output through the pass filter unit 30 and the output coupling capacitor (C ₆ ) in order.

At this time, the _first and second high frequency variable trap unit 10 provided at the connection point between the _first and second inductors L ₁ and L ₂ and the connection point between the third inductor L ₃ and the LC high pass filter 30, respectively. 20 is a tuning voltage V _T through the resistors R ₁ and R ₂ and the first inductor L _1, respectively, and the resistors R ₁ and R ₂ and the _first inductor L _1. The tuning voltage (V _T ) in series through -L ₃ ) forms a trap point of the same frequency on the high frequency side of the pass frequency.

The larger the tuning voltage (reverse bias voltage) applied to the cathode side of the _first and second varactor diodes D ₁ and D _{2 in the first} and second high frequency variable trap units 10 and 20, the _first and second bars. The capacitance value of the varactor diodes D ₁ and D ₂ decreases, so that the trap frequency point moves to the high level, and conversely, the tuning applied to the cathode side of the _first and second varactor diodes D ₁ and D ₂ . The smaller the voltage V _T is, the higher the capacitance value of these first and second varistor diodes D ₁ and D ₂ is, and eventually the trap frequency point moves toward the lower end.

In fact, when the tuning voltage V _T is changed from 0V to 22V, the trap frequency of the first and second high frequency variable traps 10 and 20 is shifted from 1700MHz to 2050MHz as referred to in FIG.

Meanwhile, the tuning voltage V _T applied to the first and second high frequency variable trap units 10 and 20 is simultaneously applied to the _third and _fourth varactor diodes D ₃ and D ₄ of the low frequency variable trap unit 40. do.

The low frequency variable trap part 40 includes variable capacitance values of the fifth inductor L ₅ and the third varactor diode D ₃ , and the sixth inductor L ₆ and the fourth varactor diode D ₄ . The variable capacitance causes trap formation on the low frequency side.

In fact, when the tuning voltage V _T is changed from 0V to 22V, the trap frequency of the low frequency variable trap unit 40 moves from 950MHz to 1200MHz.

Thus, the first and second high-frequency variable trap portions 10 and 20 and low-frequency variable trap portion 40 is the subject innovation, the solid line (C) in FIG. 4 according to the magnitude of the tuning voltage (V _T) which changes with and As shown by the dotted line (d), the RF signal is band-filtered by varying from 950-1700 MHz to 1200-2050 MHz with a constant bandwidth over the entire band of 950-2050 MHz.

As described above, when the input filter of the satellite broadcast tuner is extended to 2050MHz, the present invention can eliminate interference due to low-channel harmonics in high channels, thereby significantly improving image characteristics and intermodulation characteristics. You can get a satellite tuner.

Claims (1)

The RF input signal through the input coupling capacitor C ₁ is connected to the first through third inductor L ₁ -L ₃ connected in series and through the LC high frequency filter 30 having a 950 MHz cutoff frequency characteristic. In addition, a connection voltage V _T is applied to a connection point between the input coupling capacitor C ₁ and the first inductor L ₁ , and the first inductor L ₁ and the second inductor L _{2 are applied.} ) Is connected to the first varactor diode (D ₁ ) and the anode side of the _first varactor diode (D ₁ ) in series with the proportional capacitor (C ₃ ) connected to the ground and the first inductor (L) ₁ ) a first high frequency trap unit 10 having a trap point determined between 1700-2050 MHz according to the size of the tuning voltage V _T applied through the second inductor; and the second inductor L ₂ and the third inductor. an inductor (L _3), the respective anode side of the third and fourth varactor diode ground connection points between the (D _3, D _4), and their third and fourth varactor die De (D _3, D ₄₎ is composed of a second inductor 5 and 6 (L _5, L ₆₎ respectively connected in series to the cathode side of which is applied through the first and second inductors (L _1, L ₂₎ in series, A low frequency variable trap unit 40 having a trap point is determined between 950-1200 MHz according to the size of the tuning voltage V _T , and between the third inductor L ₃ and the LC high pass filter 30. in the connection point, the anode of the second varactor diode (D ₂₎ with a diode (D ₂₎ and a second varactor diode (D ₂₎ the rate adjustment capacitor connected in series to the anode-side ground (C ₄₎ The second high frequency variable trap unit 20 is configured and the trap point is determined between 1700-2050 MHz according to the magnitude of the tuning voltage V _T in series through the 1-3 inductors L _1- L ₃ . Broadband variable input filter circuit of a satellite broadcast tuner, characterized in that configuration.