KR100375631B1 - Digital compact tuner - Google Patents

Abstract

The present invention provides a double conversion tuner including an RF unit, a primary mixer unit, a primary IF unit, a secondary mixer unit, and a secondary IF unit, wherein the primary IF unit is output from the primary mixer unit. A first IF filter that passes only signals of a desired band among first intermediate frequency signals, a first IF filter that is a dielectric filter, a first IF amplifier that amplifies a first intermediate frequency signal passed from the first IF filter, and an output from the IF amplifier And a low pass filter comprising two stages of the inductor and the capacitor to remove the harmonic signal and the bit signal among the first intermediate frequency signals.

Therefore, according to the present invention configured as described above, by installing a low pass filter in the primary IF unit to remove the harmonics of the 2 ~ 3GHz band generated during tuning of the tuner 429MHz, 475MHz to minimize the number of bits appearing in the final intermediate frequency output It is.

Description

Digital compact tuner {DIGITAL COMPACT TUNER}

The present invention relates to a tuner, and more particularly, by adding a low pass filter consisting of an inductor and a capacitor to the output side of a primary IF amplifier of a digital small tuner to block harmonics between 2 and 3 MHz. 475MHz) and a digital miniature tuner to remove beat forces when selected.

Digital small tuners are commonly used in set-top boxes, PCs, and cable modems.

As shown in FIG. 1, the digital compact tuner 10 includes an RF unit 20, a primary mixer unit 30, a primary IF unit 40, a secondary mixer unit 50, and a secondary unit. It consists of an IF unit 60.

The RF unit 20 is composed of an AGC 21, an RF amplifier 22, and an RF filter 23.

First, the AGC 21 automatically adjusts the output of the video signal constantly even if the magnitude of the high frequency signal induced by the antenna ANT changes.

The RF amplifier 22 amplifies the high frequency signal passing through the AGC 21.

The RF filter 23 selects a desired high frequency signal from the high frequency signals amplified by the RF amplifier 22.

The primary mixer section 30 is composed of a primary PLL 31, a primary local oscillator 32, and a primary mixer 33.

The primary phase locked loop (PLL) 31 stores channel data therein, and outputs a control voltage to the primary local oscillator 32 according to external control.

The primary local oscillator 32 is divided into three bands and switches the bands according to the frequency at the time of channel tuning, and generates a predetermined oscillation frequency according to the control voltage of the primary PLL 31 and outputs it to the primary mixer 33. .

In addition, the primary mixer 33 mixes the high frequency signal selected by the RF filter 23 and the oscillation frequency generated by the primary local oscillator 32 to output the primary intermediate frequency.

The primary IF unit 40 is composed of a primary IF filter 41 and a primary IF amplifier 42.

The primary IF filter 41 passes only the desired intermediate frequency signal of the primary intermediate frequency signals output from the primary mixer 33, and a dielectric filter is used.

The primary IF amplifier 42 amplifies the primary intermediate frequency signal output from the primary IF filter 41.

The secondary mixer section 50 is composed of a secondary PLL 51, a secondary local oscillator 52, and a secondary mixer 53.

The secondary phase locked loop (PLL) 51 stores channel data therein, and outputs a control voltage to the secondary local oscillator 52 according to external control.

The secondary local oscillator 52 is divided into three bands and switches the bands according to the frequency at the time of channel tuning, and generates a predetermined oscillation frequency according to the control voltage of the secondary PLL 51 and outputs the generated oscillation frequency to the secondary mixer 53. .

The secondary mixer 53 mixes the intermediate frequency signal amplified by the primary IF amplifier 42 of the primary IF unit 40 and the oscillation frequency generated by the secondary local oscillator 52 to convert the secondary intermediate frequency. Output

The secondary IF unit 60 is composed of a secondary IF filter 61 and a secondary IF amplifier 62.

The secondary IF filter 61 passes only signals of a desired band among the secondary intermediate frequency signals output from the secondary mixer 53.

The secondary IF amplifier 62 is composed of a plurality of amplifiers to amplify and output the secondary intermediate frequency signal output through the secondary IF filter 61 to a desired level.

In such a digital small tuner, mutual interference between a primary local oscillator and a secondary local oscillator is generated. Since the dielectric filter is used in the primary IF unit, the passband characteristics are good, but the oscillation frequency rejection characteristics are insufficient.

Therefore, an object of the present invention is to solve the above problems, by installing a low pass filter in the first IF unit to remove the harmonics of the 2 ~ 3GHz band generated during tuning of the tuner 429MHz, 475MHz in the final intermediate frequency output This is to minimize the number of bits shown in the.

1 is a block diagram schematically showing a conventional digital small tuner

2 is a block diagram schematically showing a digital small tuner according to the present invention;

3 is a block circuit diagram showing a configuration of a trap circuit according to the present invention.

Figure 4 is a graph showing the characteristics of the IF unit according to the present invention

<Explanation of symbols for main parts of the drawings>

100: 1st IF unit 110: 1st IF filter

120: first-order IF amplifier 130: low pass filter

C1, C2: Capacitors L1, L2: Inductors

Features of the present invention for achieving the above object,

In the double conversion type tuner consisting of an RF unit, a primary mixer unit, a primary IF unit, a secondary mixer unit, and a secondary IF unit,

The primary IF unit,

A first IF filter which passes only signals of a desired band among the first intermediate frequency signals output from the first mixer, and a dielectric filter;

A first IF amplifier for amplifying the first intermediate frequency signal passed from the first IF filter,

And a low pass filter for removing harmonic signals and bit signals among the first intermediate frequency signals output from the IF amplifier.

Here, the low pass filter consists of two stages.

Hereinafter, the configuration and operation of the digital compact tuner according to the present invention will be described in detail with reference to FIGS. 2 and 4. In FIG. 2, the same parts as those of the conventional digital compact tuner shown in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted.

Figure 2 is a block diagram schematically showing a digital small tuner according to the present invention, Figure 3 is a block circuit diagram showing the configuration of the trap circuit according to the present invention, Figure 4 is a graph showing the characteristics of the IF unit according to the present invention Figure 2 4, the first IF unit 100 of the digital small tuner 10 according to the present invention may include a first IF filter 110, a first IF amplifier 120, and a low pass filter 130. It is composed.

The primary IF filter 110 passes only the desired intermediate frequency signal among the primary intermediate frequency signals output from the primary mixer 33.

The primary IF amplifier 120 amplifies the primary intermediate frequency signal output from the primary IF filter 110.

The low pass filter 130 cuts harmonics in the 2 to 3 GHz band among the primary intermediate frequency signals output through the primary IF amplifier 120 to remove the bit forces formed during the tuning of 431 MHz and 475 MHz. Here, the low pass filter 130 has two stages of an inductor and a capacitor. L1 is 2.2nH, L2 is 5.6nH, C1 is 1.5pF, and C2 is 5pF.

When the low pass filter 133 is configured as described above, harmonics of 2 to 3 GHz are removed as shown in FIG. 4 of the first intermediate frequency signal output through the first IF amplifier 120.

This removes the bit forces that were formed when tuning the tuner 10 to 431 MHz and 475 MHz. In addition, since the forces of the local oscillator are induced not only through the primary IF unit 100 but also through various paths inside the tuner, it is necessary to block harmonics in other parts as much as possible, and further enhance the rejection characteristic of 3GHz or more in the primary IF unit. If you do this, you can expect a lot of effects in other channels, but depending on how you do the cover contact of the chassis rather than circuit, it is sensitive in the high frequency band, and it is difficult to implement all channels in circuit, thus improving only the removal characteristic of the 2 ~ 3GHz band.

As described above, according to the digital compact tuner according to the present invention, a low pass filter is installed in the primary IF unit to remove harmonics in the 2 to 3 GHz band generated when tuning the tuner at 429 MHz and 475 MHz. You can minimize the number of bits that appear.

Claims (2)

In the double conversion type tuner consisting of an RF unit, a primary mixer unit, a primary IF unit, a secondary mixer unit, and a secondary IF unit, The primary IF unit, A first IF filter which passes only signals of a desired band among the first intermediate frequency signals output from the first mixer, and a dielectric filter; A first IF amplifier for amplifying the first intermediate frequency signal passed from the first IF filter, And a low pass filter having two stages of an inductor and a capacitor to remove harmonic signals and bit signals among the first intermediate frequency signals output from the IF amplifier. delete