KR20050008019A - Double conversion type tuner having wide variable range agc - Google Patents

Abstract

PURPOSE: A double conversion type tuner provided with an automatic gain control(AGC) having a wide variable range is provided to drastically improve the performance of receiver by lowering the power level at the tuner input terminal. CONSTITUTION: A double conversion type tuner(100) provided with an automatic gain control(AGC) having a wide variable range includes a secondary AGC(110) and an AGC detector(120). The secondary AGC is connected between the output terminal of the primary mixer(17) and the input terminal of the primary IF amplifier(18) and controlled in response to the control signal inputted from the outside. The secondary AGC controls the gain constant although the size of the primary intermediate frequency signal outputted from the primary mixer is changed. The AGC detector is connected between the output terminal of the secondary mixer(22) and the input terminal of the secondary IF filter(23) to detect the level of the secondary intermediate frequency signal outputted from the secondary mixer. And, the AGC detector outputs the control signal to control the gain of the secondary AGC.

Description

DOUBLE CONVERSION TYPE TUNER HAVING WIDE VARIABLE RANGE AGC}

The present invention relates to a double-conversion tuner, specifically, by inserting the AGC and AGC detector into the circuit to design an AGC having a variable range of 50 to 60 dB by lowering the power level at the tuner input stage when a strong electric field is input. The present invention relates to a double conversion type tuner having an AGC having a wide variable range to prevent performance degradation caused by a strong electric field.

In general, a tuner is a device that receives an RF signal (radio frequency signal) through an antenna, converts it into an IF signal (intermediate frequency signal), detects it, and separates it into a video signal and an audio signal to output it. Such a tuner includes a single conversion type for outputting an intermediate frequency and a double conversion method for amplifying and mixing a primary intermediate frequency signal and converting the signal into a secondary intermediate frequency.

As shown in FIG. 1, the double conversion tuner 10 includes an AGC 11, a tracking filter 12, an RF filter 13, an RF amplifier 14, and a primary PLL IC ( 15), primary local oscillator 16, primary mixer 17, primary IF amplifier 18, primary IF filter 19, secondary PLL IC 20, secondary It consists of a local oscillator 21, a secondary mixer 22, a secondary IF filter 23, and a secondary IF amplifier 24.

The AGC 11 automatically adjusts the output of the video signal constantly even if the magnitude of the high frequency signal induced by the antenna (not shown) changes.

The tracking filter 12 removes noise included in a signal of a high frequency band received by the antenna and passes only a desired high frequency (RF) signal.

The RF filter 13 passes only signals of a desired band among the high frequency signals input through the tracking filter 12.

The RF amplifier 14 amplifies the high frequency signal passed through the RF filter 13.

The primary phase locked loop (PLL) IC 15 stores channel data therein and outputs a control voltage to the primary local oscillator 16 according to external control.

The primary local oscillator 16 is divided into three bands, and the band is switched according to the channel tuning frequency, and the oscillation frequency is generated according to the control voltage of the primary PLL IC 15 and output to the primary mixer 17.

The primary mixer 17 mixes the high frequency signal amplified by the RF amplifier 14 and the oscillation frequency generated by the primary local oscillator 16 to output the primary intermediate frequency.

The primary IF amplifier 18 amplifies the primary intermediate frequency signal output from the primary mixer 17.

The primary IF filter 19 passes only the desired intermediate frequency signal of the primary intermediate frequency signals output from the primary IF amplifier 18.

The secondary PLL IC 20 stores channel data therein and outputs a control voltage to the secondary local oscillator 21 according to external control.

The secondary local oscillator 21 is divided into three bands and switches the bands according to the frequency at the time of channel selection, and generates an oscillation frequency according to the adjustment of the secondary PLL IC 20 and outputs them to the secondary mixer 22.

The secondary mixer 22 mixes the intermediate frequency signal amplified by the primary IF amplifier 18 and the oscillation frequency generated by the secondary local oscillator 21 to output the secondary intermediate frequency.

The secondary IF filter 23 passes only signals of a desired band among the secondary intermediate frequency signals output from the secondary mixer 22.

The secondary IF amplifier 24 amplifies and outputs the secondary intermediate frequency signal output through the secondary IF filter 23 to a desired level.

The double conversion tuner 10 is composed of an AGC 11, a tracking filter 12, an RF filter 13, and an RF amplifier 14 to tune a desired channel among TV signals input through an antenna. When the input section produces some tuning waveform, it passes through a primary mixer section consisting of a primary PLL IC 15, a primary local oscillator 16, and a primary mixer 17, followed by a primary IF amplifier 18. ) And up-converting to the first IF frequency in the first IF section consisting of the first IF filter 19, which in turn is the second PLL IC 20, the second local oscillator 21, and the second mixer ( After passing through the secondary mixer section 22), the secondary IF filter 23 and the secondary IF section composed of the secondary IF amplifier 24 are down-converted to the final intermediate frequency.

However, in the conventional double conversion type tuner, there is a limit on the variable range that one AGC can have. Therefore, due to the nonlinear characteristics of the active elements in the next block when a strong electric field is input, the inter-modulation or Image quality and other performance deterioration due to the beat (Beat), etc., and also due to this, there is a problem that the adjacent channel characteristics significantly deteriorate. If the pin diodes are used in series to improve the variable range of the AGC, the variable range is extended but the sensitivity characteristics deteriorate.

Therefore, an object of the present invention is to solve the above problems, by inserting the AGC and AGC detector in the circuit portion by lowering the power level at the tuner input stage when a strong field input, the intermodulation or bit that may occur when a strong field input to the strong field The performance of the receiver can be greatly improved, and the performance of the adjacent channel can be greatly improved.

1 is a block diagram schematically showing the configuration of a conventional double conversion type tuner.

2 is a block diagram schematically showing the configuration of a double conversion type tuner having an AGC having a wide variable range according to the present invention.

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

11: 1st AGC 12: Tracking Filter

13: RF filter 14: RF amplifier

15: Primary PLL IC 16: Primary Local Oscillator

17: 1st mixer 18: 1st IF amplifier

19: 1st IF Filter 20: 2nd PLL IC

21: 2nd local oscillator 22: 2nd mixer

23: 2nd IF filter 24: 2nd IF amplifier

110: 2nd AGC 120: AGC detector

Features of the present invention for achieving the above object,

Primary AGC, Tracking Filter, RF Filter, RF Amplifier, Primary PLL IC, Primary Local Oscillator, Primary Mixer, Primary IF Amplifier, Primary IF Filter, Secondary PLL IC In a double conversion tuner including a second local oscillator, a second mixer, a second IF filter, and a second IF amplifier,

It is connected between an output terminal of the primary mixer and an input terminal of the primary IF amplifier and controlled according to a control signal input from the outside, so that the gain is constantly adjusted even if the magnitude of the primary intermediate frequency signal output from the primary mixer changes. With the second AGC,

A control signal connected between an output terminal of the secondary mixer and an input terminal of the secondary IF filter to sense a level of a secondary intermediate frequency signal output from the secondary mixer and adjust a gain of the secondary AGC according to a magnitude; It further comprises an AGC detector for outputting.

Hereinafter, the configuration of a double conversion type tuner having an AGC having a wide variable range according to the present invention will be described in detail with reference to FIG. In FIG. 2, the same code | symbol as FIG. 1 is attached | subjected about the same part as the tuner of the double conversion system shown in FIG.

2 is a block diagram schematically illustrating a configuration of a double conversion type tuner having an AGC having a wide variable range according to the present invention.

Referring to FIG. 2, a double conversion tuner 100 having an AGC having a wide variable range according to the present invention includes a primary AGC 11, a tracking filter 12, an RF filter 13, RF amplifier 14, primary PLL IC 15, primary local oscillator 16, primary mixer 17, secondary AGC 110, primary IF amplifier 18, Primary IF filter 19, secondary PLL IC 20, secondary local oscillator 21, secondary mixer 22, AGC detector 120, secondary IF filter 23 And a secondary IF amplifier 24.

The primary AGC 11 automatically adjusts the output of the video signal at all times even when the magnitude of the high frequency signal induced by the antenna ANT changes.

The tracking filter 12 removes noise included in a signal of a high frequency band received by the antenna ANT and passes only a desired high frequency (RF) signal.

The RF filter 13 passes only signals of a desired band among the high frequency signals input through the tracking filter 12.

The RF amplifier 14 amplifies the high frequency signal passed through the RF filter 13.

The primary PLL IC 15 stores channel data therein, and outputs a control voltage to the primary local oscillator 16 according to external control.

The primary local oscillator 16 is composed of a 1-band tank circuit having a wide range, and generates an oscillation frequency corresponding to a channel according to the control voltage of the primary PLL IC 15 and outputs it to the primary mixer 17. do.

The primary mixer 17 mixes the high frequency signal amplified by the RF amplifier 14 and the oscillation frequency generated by the primary local oscillator 16 to output the primary intermediate frequency.

The secondary AGC 110 is controlled according to a control signal input from the outside to constantly adjust the gain even if the magnitude of the primary intermediate frequency signal output from the primary mixer 17 changes.

The primary IF amplifier 18 amplifies the primary intermediate frequency signal output from the primary mixer 17 via the secondary AGC 110.

The primary IF filter 19 passes only the desired intermediate frequency signal of the primary intermediate frequency signals output from the primary IF amplifier 18.

The secondary PLL IC 20 stores channel data therein and outputs a control voltage to the secondary local oscillator 21 according to external control.

The secondary local oscillator 21 is composed of a one-band tank circuit, and generates a fixed oscillation frequency by the control voltage of the secondary PLL IC 20 and outputs it to the primary mixer 17.

It is divided into three bands and the band is switched according to the frequency at the time of channel selection, and the oscillation frequency is generated according to the adjustment of the secondary PLL IC 20 and output to the secondary mixer 22.

The secondary mixer 22 mixes the intermediate frequency signal amplified by the primary IF amplifier 18 and the oscillation frequency generated by the secondary local oscillator 21 to output the secondary intermediate frequency.

The AGC detector 120 senses the level of the secondary intermediate frequency signal output from the secondary mixer 22 and outputs a control signal for adjusting the gain of the secondary AGC 110 according to the magnitude.

The secondary IF filter 23 passes only signals of a desired band of secondary intermediate frequency signals output from the secondary mixer 22 through the AGC detector 120.

The secondary IF amplifier 24 amplifies and outputs the secondary intermediate frequency signal output through the secondary IF filter 23 to a desired level.

Hereinafter, an operation of a double conversion type tuner having an AGC having a wide variable range according to the present invention will be described in detail with reference to FIG. 2.

The operation of each component is the same as the conventional operation, except that the AGC detector 120 senses the level of the secondary intermediate frequency signal to adjust the gain of the secondary AGC 110 according to the size.

On the other hand, the tuner of the broadcast receiver RF receiver uses AGC to control the power level according to the signal power level of the field.In the case of the digital terrestrial broadcast (North American) double conversion type tuner, the AGC 1 stage using a pin diode is used. The set requires 90dB levels, including IF AGC (50dB). In other words, the tuner requires more than 40dB of AGC variable range, but due to the characteristics of the pin diode, only 25 ~ 30dB is available with the AGC 1 stage.

Therefore, the AGC detector 120 for controlling the secondary AGC 110 and the secondary AGC 110 at the rear end of the primary mixer 17 of the tuner is additionally installed at the rear end of the secondary mixer 22. Is designed to have a wide variable range of 50 ~ 60dB, which can greatly improve the performance of the receiver due to intermodulation or bits that may occur during strong field inputs, and can also greatly improve the performance of adjacent channels. AGC can be controlled by itself. In addition, additional pin diodes in front of the tuner can improve the degradation of sensitivity characteristics.

As described above, according to the double-conversion tuner having the AGC having a wide variable range according to the present invention, the AGC and AGC detectors are inserted into the circuit portion to lower the power level at the tuner input stage when inputting the strong electric field to the strong electric field. The performance of the receiver due to intermodulation or bits that may occur during system input can be greatly improved, and the performance of adjacent channels can be greatly improved.

Claims (1)

Primary AGC, Tracking Filter, RF Filter, RF Amplifier, Primary PLL IC, Primary Local Oscillator, Primary Mixer, Primary IF Amplifier, Primary IF Filter, Secondary PLL IC In a double conversion tuner including a second local oscillator, a second mixer, a second IF filter, and a second IF amplifier, It is connected between an output terminal of the primary mixer and an input terminal of the primary IF amplifier and controlled according to a control signal input from the outside, so that the gain is constantly adjusted even if the magnitude of the primary intermediate frequency signal output from the primary mixer changes. With the second AGC, A control signal connected between an output terminal of the secondary mixer and an input terminal of the secondary IF filter to sense a level of a secondary intermediate frequency signal output from the secondary mixer and adjust a gain of the secondary AGC according to a magnitude; A double conversion tuner having an AGC having a wide variable range, characterized in that it further comprises an AGC detector for outputting.