KR20010055283A - Three band tracking filter for digital satellite broadcasting tuner - Google Patents

Abstract

PURPOSE: A 3-band tracking filter for a digital satellite broadcasting tuner is provided to connecte diodes in series for minimizing a capacity of each diode and accurately performe a switching. CONSTITUTION: First to third input switching units(100,300,500) are switched according to a band switching signal and a voltage(B+). First to third output switching units(200,400,600) are switched according to an other band switching signal for preventing an error operation of the first to third input switching units(100,300,500).

Description

THREE BAND TRACKING FILTER FOR DIGITAL SATELLITE BROADCASTING TUNER}

The present invention relates to a digital satellite broadcast tuner, and more particularly, to a digital satellite broadcast tuner to ensure that the switching operation of the switching unit of the three-band tracking filter of the digital satellite broadcast tuner to prevent other bands from affecting the band switching. To a three-band tracking filter.

In general, the digital satellite tuner is a reception tuner that can receive digital satellite broadcast directly to a TV without going through a satellite relay station. It can solve high visual acuity, high fidelity broadcasting, and multiple voice broadcasting. It is a product that supports HDTV, which is a key component that enables simultaneous viewing in a wide range of regions.

The digital satellite broadcast tuner includes a three-band tracking filter that removes noise included in a signal of a high frequency band received by an antenna (not shown) and passes only a desired RF signal by a tuning voltage.

As shown in FIGS. 1 and 2, the three-band tracking filter unit is switched according to a band switching signal applied from a microcomputer (not shown) in the system and a voltage (B ⁺ ) of a power supply terminal to open or short the line. First to third input switching units 11, 21, and 31 for inputting RF signals to the first to third tracking filters 12, 22, and 32, and only RF signals of a desired band by a tuning voltage among the input RF signals. First to third tracking filters 12, 22, and 32, and first to third output switching units 13, 23, and 33 for outputting an RF signal output from the first to third tracking filters 12, 22, and 32. It is composed of In the figure, reference numeral C denotes a capacitor for removing noise components of the RF signal. Each input switching unit 11, 21, 31 and each output switching unit 13, 23, 33 are constituted by the same circuit and operated identically.

FIG. 2 is a diagram illustrating in more detail the first input switching unit 11 and the first output switching unit 13 of FIG. 1. In FIG. 2, the first input switching unit 11 includes a diode D ₁ having an anode connected to an RF input terminal and a cathode connected to an input terminal of the first tracking filter 12, and a cathode connected to the cathode of the diode D ₁ in parallel. A diode D ₂ having an anode connected to the band switching signal output terminal of the microcomputer, and a resistor R ₁ having _one end connected in parallel to the cathode of the diode D ₁ and the diode D ₂ and the other end grounded to ground.

The first output switching section 13 has an anode connected to the RF output stage and of claim 1 to 3 and a diode D ₃ such that its cathode is connected respectively to an output of the tracking filter 12, the cathode is parallel coupled to the cathode of the diode D ₃ And a diode D ₄ having an anode connected to the band switching signal output terminal of the microcomputer, and a resistor R ₂ having one end connected in parallel to the cathode of the diode D ₃ and the diode D ₄ and the other end grounded to ground.

Looking at the operation of the switching unit of the conventional three-band tracking filter, the microcomputer operates each switching unit to pass only the signal of the desired band of the RF signal, the first input switching unit when passing the signal of 50 ~ 170MHz band (11) and the first output switching section 13 are turned on, and the second and third input switching sections 21 and 31 and the second and third output switching sections 23 and 33 are turned off. When the signal of 170 to 470 MHz band is passed, the second input switching unit 21 and the second output switching unit 23 are turned on, and the first and third input switching units 11 and 31 and the first and third units are turned on. The output switching sections 13 and 33 are turned off. In addition, when passing a signal in the 470 to 800 MHz band, the third input switching unit 31 and the third output switching unit 33 are turned on, and the first and second input switching units 11 and 21 and the first and second units are switched on. The output switching sections 13 and 23 are turned off.

When the microcomputer inputs a band switching signal having a voltage lower than the voltage of the power supply terminal B ⁺ to turn on the first input switching unit 11 and the first output switching unit 13, the diode D ₂ , the diode D _4. Diode D ₂ , diode D ₄ are turned off because the voltage difference between anode and cathode is less than the operating voltage. Thus, the voltage difference between the anode of the diode D ₁ , the diode D ₃ and the cathode is greater than the operating voltage, and the diode D ₁ , the diode D ₃ is turned on.

At this time, the microcomputer has a voltage higher than the voltage (B ⁺ ) of the power supply terminal to turn off the second and third input switching units 21 and 31 and the second and third output switching units 23 and 33. When the band switching signal having a signal is input, the second and third input switching parts 21 and 31 and the second and third output switching parts 23 and 33 are turned off.

Then, the first input switching unit 11 and the first output switching unit 13 are turned on, and the second and third input switching units 21 and 31 and the second and third output switching units 23 and 33 are turned off. The RF signal is input to the first tracking filter 12 through the first input switching unit 11, and the first tracking filter 12 outputs an RF signal in a 50 to 170 MHz band according to the tuning voltage. The RF signal is output through the one output switching unit 13.

However, such a conventional switching unit has a problem in that the diodes are turned on even when the capacitance of each diode is turned off because each diode is connected in parallel to affect other bands.

In addition, since each diode is applied with an unstable voltage, there is a problem that the capacity and impedance of the diode are unstable.

The present invention is to solve the above problems, the object of each diode is connected in series to reduce the capacity of each diode to ensure a reliable switching to prevent affecting other bands.

In addition, another object of the present invention is to apply a stable voltage to each diode to stabilize the capacitance and impedance of the diode.

1 is a block circuit diagram showing a three-band tracking filter of a conventional digital satellite tuner.

FIG. 2 is a block circuit diagram illustrating a switching unit of the 3-band tracking filter of FIG. 1.

3 is a block circuit diagram illustrating a 3-band tracking filter of a digital satellite broadcast tuner according to the present invention.

4 is a block circuit diagram illustrating a switching unit of the three-band tracking filter of FIG. 3.

<Description of the symbols for the main parts of the drawings>

10: 3-band tracking filter 11, 100: first input switching unit

21, 300: second input switching unit 31, 500: third input switching unit

13, 200: first output switching unit 23, 400: second output switching unit

33, 600: third output switching unit 110: first input band switching unit

120: first input other band switching unit D ₁₀ ~ D _{60 ,} : diode

L ₁₀ to L ₄₀ : Coil R ₁₀ to R ₁₀₀ : Resistance

3 band tracking filter of the digital satellite broadcast tuner for achieving the above object,

A tuning filter passes only an RF signal of a desired band by a tuning voltage, and is connected to an input terminal and an output terminal of the tracking filter, respectively, and is switched in accordance with a band switching signal output from a band switching signal output terminal of a microcomputer in the system and a voltage of a power supply terminal. In the three-band tracking filter of the digital satellite tuner comprising a switching unit for opening or shorting a line to input the RF signal input from the RF input terminal to the tracking filter,

A first switching unit switched according to the band switching signal and the voltage of the power supply terminal;

And a second switching unit which is switched according to another band switching signal to prevent a malfunction of the input switching unit.

Here, the first switching unit, the anode is connected in series with the RF input terminal and the RF output terminal is switched in accordance with the difference between the voltage applied through the power supply terminal and the band switching signal output to the band switching signal output terminal to open the line and Difference between the first diode to short-circuit, the anode is connected in series with the cathode of the first diode, the cathode is connected to the tracking filter, the voltage applied through the power supply terminal and the band switching signal output to the band switching signal output terminal A first diode switched in accordance with the second diode to open and short the line, a first coil connected in parallel between the RF input terminal and the RF output terminal, and an anode of the first diode to alternatingly block the first diode; One end is connected to the first coil in series, the other end is connected to the power supply terminal to drop the input voltage A second coil connected in parallel between a resistor and a cathode of the second diode and the tracking filter to alternatingly block the second diode, and one end connected in series to the second coil, and the other end to the microcomputer. A second resistor connected to drop the voltage and a third resistor and a fourth resistor connected in parallel to the anode of the first diode and the cathode of the second diode to apply a stable voltage to the first diode and the second diode. Include,

The second switching unit has an anode connected in parallel between the cathode of the second diode and the tracking filter, the cathode is grounded through a resistor, and switched according to a voltage input from the other band switching signal output terminal of the microcomputer. It characterized in that it comprises a third diode.

Hereinafter, the configuration and operation of the three-band tracking filter of the digital satellite broadcast tuner according to the present invention will be described in detail with reference to FIG.

3 is a block circuit diagram illustrating a three-band tracking filter of the digital satellite broadcast tuner according to the present invention, and FIG. 4 is a block circuit diagram illustrating a switching unit of the three-band tracking filter of FIG. 3.

3 and 4, the switching unit according to the first to third input switching unit (100, 300, 500) and other band switching signal that is switched according to the band switching signal and the voltage (B ⁺ ) of the power supply terminal It is composed of the first to third output switching unit (200, 400, 600) is switched to prevent the malfunction of the first to third input switching unit (100, 300, 500).

The first input switching unit 100 includes a first input band switching unit 110 and a first output other band switching unit 120.

The first input band switching unit 110 includes a diode D ₁₀ , a diode D ₂₀ , a coil L ₁₀ , a resistor R ₁₀ , a coil L ₂₀ , a resistor R ₂₀ , a resistor R _30, and a resistor R ₄₀ . .

The diode D ₁₀ has an anode connected in series to an RF input terminal, the diode D ₂₀ has an anode connected in series with a cathode of the diode D ₁₀ , and a cathode is connected to the first tracking filter 12.

The coil L ₁₀ is connected in parallel between the RF input terminal and the anode of the diode D ₁₀ , the resistor R ₁₀ is connected in series with the coil L ₁₀ , and the other end is connected with the power supply terminal.

The coil L ₂₀ is connected in parallel between the cathode of the diode D ₂₀ and the first tracking filter 12, the resistor R ₂₀ is connected in series with the coil L ₂₀ , and the other end is connected with the band switching signal output terminal of the microcomputer.

R ₃₀ and R ₄₀ are connected in parallel to the anode of diode D ₁₀ and the cathode of diode D ₂₀ .

The first input other band switching unit 120 includes a diode D ₃₀ , a resistor R _50, and a capacitor C.

Diode D ₃₀ is a diode D ₂₀ is an anode between the cathode and the input terminal of the first tracking filter 12 is a parallel connected, via a resistor R ₅₀ and the cathode is grounded, of the microcomputer to the cathode and the resistor R ₅₀ node The other band switching signal output terminal is connected. Here, the capacitor C removes the noise component of the other band switching signal.

The first output switching unit 200 is composed of a first output band switching unit 210, and the first output other band switching unit 220.

The first output band switching unit 110 includes a diode D ₄₀ , a diode D ₅₀ , a coil L ₃₀ , a resistor R ₆₀ , a coil L ₄₀ , a resistor R ₇₀ , a resistor R _80, and a resistor R ₉₀ . .

The diode D ₄₀ has an anode connected in series to the RF output terminal, the diode D ₅₀ has an anode connected in series with the cathode of the diode D ₄₀ , and a cathode is connected to the output terminal of the first tracking filter 12.

The coil L ₃₀ is connected in parallel between the RF output terminal and the anode of the diode D ₄₀ , and the resistor R ₆₀ is connected in series to the coil L ₃₀ and the other end to the power supply terminal.

The coil L ₄₀ is connected in parallel between the cathode of the diode D ₅₀ and the output terminal of the first tracking filter 12, the resistor R ₇₀ is connected in series with the coil L ₄₀ , and the other end is connected with the band switching signal output terminal of the microcomputer. do.

R ₈₀ and R ₉₀ are connected in parallel to the anode of diode D ₄₀ and the cathode of diode D ₅₀ .

The first output other band switching unit 120 includes a diode D ₆₀ , a resistor R _100, and a capacitor C.

Diode D ₆₀ is a diode D ₅₀ is an anode between the cathode and the output terminal of the first tracking filter 12 is a parallel connected, via a resistor R ₁₀₀ and the cathode is grounded, of the microcomputer to the cathode and the resistor R ₁₀₀ Node The other band switching signal output terminal is connected. Here, the capacitor C removes the noise component of the other band switching signal. Here, the second and third input switching units 300 and 500 and the second and third output switching units 400 and 600 may be formed of the same circuit as the first input switching unit 100 and the first output switching unit 200. Configured and operated identically.

Hereinafter, the operation of the 3-band tracking filter of the digital satellite broadcasting tuner according to the present invention will be described in detail with reference to FIGS. 3 and 4.

First, when a voltage B ⁺ having a predetermined magnitude is input from the power supply terminal, a DC voltage is transmitted through the resistor R ₁₀ and the coil L ₁₀ of the first input band switching unit 110 of the first input switching unit 100 to the diode D _10. It is input to the anode side of.

In this state, when the microcomputer outputs a voltage having a predetermined magnitude through the band switching signal output terminal to turn on the first input switching unit 100, the first input band switching unit 110 of the first input switching unit 110 is provided. The DC voltage is input through the resistor R ₂₀ and the coil L ₂₀ to the cathode of the diode D ₂₀ of the first input band switching unit 110.

At this time, the magnitude of the voltage input to the anode of the diode D ₁₀ of the first input band switching unit 110 and the magnitude of the voltage input to the cathode of the diode D ₂₀ of the first input band switching unit 110, each diode D When the difference between the operating voltages of ₁₀ and D ₂₀ (0.7 V in the case of silicon diodes and 0.3 V in the case of germanium diodes) is greater, diodes D ₁₀ and D ₂₀ of the first input band switching unit 110 are turned on. Here, the resistors R ₃₀ and R ₄₀ of the first input band switching unit 110 apply a constant voltage to the diodes D ₁₀ and D ₂₀ .

On the other hand, the cathode of the diode D ₃₀ of the first input other band switching unit 120 is connected to the second and third input switching units 300 and 500 and the second and third output switching units 400 and 600 through a band switching signal output terminal. Diode D ₃₀ remains off because a high band switching signal is input to turn it off.

When the second input switching unit 300 and the second output switching unit 400 are turned on in the microcomputer, the first input switching unit 100, the first output switching unit 200, and the third input switching unit as described above. The unit 500 and the third output switching unit 600 are turned off.

In addition, when the third input switching unit 500 and the third output switching unit 600 are turned on in the microcomputer, the first input switching unit 100, the first output switching unit 200, and the second input switching unit as described above. The unit 300 and the second output switching unit 400 are operated.

When a voltage B ⁺ of a predetermined magnitude is input from the power supply terminal, the first output switching unit 200 also performs the same operation as the first input switching unit 100. Referring to the operation, the first output switching unit ( The DC voltage is input to the anode side of the diode D ₄₀ through the resistor R ₆₀ and the coil L ₃₀ of the first output band switching unit 210 of 200.

When a voltage having a predetermined magnitude is output through the band switching signal output terminal from the microcomputer, the DC voltage is reduced through the resistor R _{70 and the} angle coil L ₄₀ of the first output band switching unit 210 of the first output switching unit 200. It is input to the cathode of the diode D ₅₀ of the one output band switching unit 210.

At this time, the magnitude of the voltage input to the anode of the diode D ₄₀ of the first output band switching unit 210 and the magnitude of the voltage input to the cathode of the diode D ₅₀ of the first output band switching unit 210 are each diode D _40. When the difference is greater than or equal to the operating voltage of D ₅₀ , the diode D ₄₀ and the diode D ₅₀ of the first output band switching unit 210 are turned on. Here, the resistors R ₈₀ and R ₉₀ of the first output band switching unit 210 apply a constant voltage to the diodes D ₃₀ and D ₄₀ .

On the other hand, the cathode of the diode D ₆₀ of the first output other band switching unit 220 is connected to the second and third input switching units 300 and 500 and the second and third output switching units 400 and 600 through a band switching signal output terminal. Diode D ₆₀ remains off because a high band switching signal is input to turn off.

When the second input switching unit 300 and the second output switching unit 400 are turned on in the microcomputer, the first input switching unit 100, the first output switching unit 200, and the third input switching unit as described above. The unit 500 and the third output switching unit 600 are turned off.

In addition, when the third input switching unit 500 and the third output switching unit 600 are turned on in the microcomputer, the first input switching unit 100, the first output switching unit 200, and the second input switching unit as described above. The unit 300 and the second output switching unit 400 are operated.

For example, the voltage B ⁺ input from the power supply terminal is 3.2V, and the band of the band switching signal output terminal for turning on the first input switching unit 100 and the first output switching unit 200. When the magnitude of the voltage of the switching signal is 1.5V (7.1V when turned off), the difference between the two voltages is 1.7V or more, so that the diodes D ₁₀ , D ₂₀ and the first output band switching unit of the first input band switching unit 110 ( Diodes D ₃₀ and D ₄₀ of 210 are turned on.

And a first input of the other diode band switching section (120) D ₃₀ and the first output when the other band switching unit, the size of 6.4V voltage input to diode D ₆₀ of 220, diode D _30, a diode reverse voltage to D ₆₀ Diode D ₃₀ and diode D ₆₀ are turned off.

In this state, in order to turn off the first input switching unit 100 and the first output switching unit 200, the diode D of the first input other band switching unit 120 receives a band switching signal having a voltage of 7.1 V in the microcomputer. ₃₀ and the diode D ₆₀ of the first output switching band 220, the diode D ₁₀ and diode D ₂₀ of the first input switching unit 110 and the diode D ₄₀ of the first output switching unit 210 and Since diode D ₅₀ has a reverse voltage, they are turned off. At the same time, since the voltage difference between the anode and the cathode of the diode D ₃₀ of the first input other band switching unit 120 and the diode D ₆₀ of the first output other band switching unit 220 is 0.7V, the diodes D ₃₀ and D ₆₀ are turned on. is the signal in the circuit is passed to the ground through a resistor R ₁₀₀ of the first type the other band, a switching unit 120, resistor R ₅₀ and the other first output band switching unit 220 of.

As a result, the switching operation can be ensured to reduce the influence on other bands during band switching.

As described above, according to the three-band tracking filter of the digital satellite broadcast tuner according to the present invention, each diode is connected in series to reduce the capacity of each diode so that reliable switching is achieved, thereby preventing the influence of other bands. can do.

In addition, it is possible to stabilize the diode's capacitance and impedance by applying a stable voltage to each diode.

Claims (2)

A tuning filter passes only an RF signal of a desired band by a tuning voltage, and is connected to an input terminal and an output terminal of the tracking filter, respectively, and is switched in accordance with a band switching signal output from a band switching signal output terminal of a microcomputer in the system and a voltage of a power supply terminal. In the three-band tracking filter of the digital satellite tuner comprising a switching unit for opening or shorting a line to input the RF signal input from the RF input terminal to the tracking filter, and transmits the RF signal output from the tracking filter to the other end, The switching unit, A first switching unit switched according to the band switching signal and the voltage of the power terminal; And a second switching unit which is switched according to another band switching signal to prevent a malfunction of the input switching unit. The method of claim 1, The first switching unit, An anode connected to the RF input terminal and the RF output terminal in series and switched according to a difference between a voltage applied through the power supply terminal and a band switching signal output to the band switching signal output terminal to open and short the line; An anode is connected in series to the cathode of the first diode, and a cathode is connected to the tracking filter to be switched according to a difference between a voltage applied through the power supply terminal and a band switching signal output to the band switching signal output terminal to open a line. And a second diode for shorting, A first coil connected in parallel between the RF input terminal and the RF output terminal and the anode of the first diode to alternatingly block the first diode; A first resistor having one end connected in series to the first coil and the other end connected to the power supply terminal to drop an input voltage; A second coil connected in parallel between the cathode of the second diode and the tracking filter to alternately block the second diode; A second resistor having one end connected in series to the second coil and the other end connected to the microcomputer to drop a voltage; A third resistor and a fourth resistor connected in parallel to the anode of the first diode and the cathode of the second diode to apply a stable voltage to the first diode and the second diode, The second switching unit, An anode is connected in parallel between the cathode of the second diode and the tracking filter, the cathode is grounded through a resistor, and the third diode is switched according to a voltage input from the other band switching signal output terminal of the microcomputer. 3-band tracking filter of the digital satellite broadcast tuner characterized in that it comprises.