KR100382653B1 - Automatic gain control system for operating based on desired signal - Google Patents

Abstract

An AGC system is disclosed that operates on the basis of a desired signal. The present invention converts a frequency of an input signal into a constant IF frequency and adjusts the signal according to the input DC component, a first filter unit for passing the IF frequency signal converted in the tuner unit only a specific band and a first An intermediate frequency amplifier for amplifying the output signal from the filter unit based on the level extracted by the level detector, a demodulator unit for demodulating the amplified signal from the intermediate frequency amplifier, and an output signal from the demodulator unit. And a second filter part which extracts a DC component and feeds it back to the tuner part. According to the present invention, by operating both the tuner and the IF AGC structure based on a desired signal, interference performance errors of adjacent signals for each set can be minimized.

Description

Automatic gain control system for operating based on desired signal

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an AGC (Automatic Gain Control) system of a digital TV (DTV), and more particularly to an AGC system operated based on a desired signal.

In general, the tuner is supplied with signals of different magnitudes, typically 0dBm -80dBm. Therefore, the receiver configures an AGC (Automatic Gain Control) circuit to apply a signal having a constant strength to the demodulator regardless of the input field strength.

1 is a block diagram of an AGC (Automatic Gain Control) system applied to a conventional DTV.

Referring to FIG. 1, an AGC system is divided into a tuner AGC and an IFF (IntermediateFrequency) AGC. The tuner AGC senses the level at the level detector 180 located in front of the SAW filters 120 and 140 and feeds it back to the tuner 110. The IF AGC outputs a direct current component through a pulse width modulation (PWM) waveform demodulated by the demodulator 170 via a low pass filter (LPF) 160, and feeds the direct current component back to the IF amplifier 150.

Typically, the tuner AGC is responsible for signals from 0 dBm to -60 dBm field strength, while the IF AGC is responsible for signals from -61 dBm to -80 dBm field strength.

However, in the AGC system as shown in FIG. 1, the level detector 180 is positioned between the output terminal of the tuner 110 and the SAW filters 12 and 140, and thus the error of the strength of the adjacent signal for each tuner according to the coil adjustment point of the actual tuner operator. Will occur a lot. Accordingly, when the adjacent signal strength of each tuner generated is converted to DC, the magnitudes of the DC components are all wrong. Therefore, even if the desired signal and the unwanted signal (undesired signal) is applied to the tuner in the same way, the DC component with the strength of the adjacent signal of the output signal is also wrong. As a result, the tuner AGC starting point (starting point) is also a problem that all the tuner is wrong.

The technical problem to be achieved by the present invention is to provide an AGC system that minimizes the error of the signal size per set by operating both the tuner AGC and IF AGC based on the desired signal (desired signal).

In order to solve the above technical problem, the present invention includes a tuner unit for converting the frequency of the input signal to a predetermined IF frequency and the size of the signal is adjusted according to the input DC component;

A first filter unit passing the IF frequency signal converted by the tuner unit only a specific band;

An intermediate frequency amplifier for amplifying the output signal from the first filter unit based on a predetermined intermediate frequency according to the level extracted by the level detector;

A demodulator unit for demodulating the signal amplified by the intermediate frequency amplifier;

An AGC system including a second filter unit for extracting a direct current component from the output signal from the demodulator unit and feeding it back to the tuner unit, and detecting a predetermined direct current level from the output signal from the filter unit It further comprises a level detector for adjusting the signal gain.

1 is a block diagram of an AGC (Automatic Gain Control) system applied to a conventional DTV.

2 is an overall block diagram of an AGC system in accordance with the present invention.

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

2 is an overall block diagram of an AGC system in accordance with the present invention.

The AGC system of FIG. 2 includes a tuner 210, a first surface acoustic wave (SAW) filter 220, a first amplifier 230, a second SAW filter 240, an IF AGC amplifier 250, and a demodulator 270. Are connected in order, and the level detector 260 is connected between the second SAW filter 240 and the IF AGC amplifier 250, and the signal output from the demodulator 270 is determined from the output signal from the filter unit. The low pass filter (LPF) 280, the second amplifier 290, and the tuner 110 are sequentially connected to detect the DC level and feed it back to the tuner 110.

Referring to FIG. 2, the tuner 210 has an AGC function for capturing an air signal of 2ch to 69ch, converting it into a constant IF frequency, and adjusting the magnitude of the signal according to an input DC component.

The first SAW filter 220 removes an unwanted frequency of an undesired signal from the IF frequencies output from the tuner 210 and passes only a desired signal of a specific band.

The first amplifier 230 amplifies the signal output from the first SAW filter 120.

The second SAW filter 240 passes only a desired signal of a specific band again among the signals output from the first amplifier 130.

The IF AGC amplifier 250 amplifies the signal output from the second SAW filter 240 around a predetermined intermediate frequency according to the DC level extracted by the level detector 260. That is, since the signal passing through the second SAW filter 240 is attenuated severely, it is amplified by the IF AGC amplifier 250 to a predetermined size.

The level detector 260 controls the IF AGC amplifier 250 by detecting a signal level below a predetermined DC level, for example, -60 dBm, from the signal output from the second SAW filter 240. That is, the level detector 260 is a starting point for further amplifying the signal in the IF AGC amplifier 250 because a signal of -60 dBm or less is input to the tuner 210 because the size of the tuner 210 is not sufficient even if the AGC of the tuner operates at maximum. The DC component of the electric field strength is detected to determine.

The demodulator 270 demodulates the modulated signal amplified by the IF AGC amplifier 250.

The LPF 280 extracts a DC component from the signal output from the demodulator 270.

The second amplifier 290 controls the AGC of the tuner 110 by amplifying the DC component output from the LPF 280. At this time, the tuner AGC is designed to operate based on a desired signal after passing through the second SAW filter 240 to operate at a signal strength of about 0dBm to -60dBm.

Therefore, according to the present invention, when a signal having an electric field strength of 0 dBm to -60 dBm is input, adjacent components are first removed while passing through the first SAW filter 220 and the second SAW filter 240. The demodulator 270 demodulates the modulated signal output from the IF AGC amplifier 250 into a PWM signal based on the purely desired signal. The PWM signal is converted into a DC component while passing through the LPF 280 and the second amplifier 290 and fed back to the tuner AGC. If a signal less than -60dBm is applied, the tuner AGC is maximized and the IF AGC is activated by the level detected by the level detector 260. Since the level detection of the tuner AGC and the IF AGC are both located at the rear ends of the SAW filters 220 and 240, the tuner AGC and the IF AGC are always constantly operated regardless of the strength of the adjacent signal or the coil adjustment point of the band pass filter of the tuner 210.

The present invention is not limited to the above-described embodiment, and of course, modifications may be made by those skilled in the art within the spirit of the present invention. That is, the present invention can be applied to all receiving systems to which AGC is applied as well as DTV.

As described above, in order to drive the tuner AGC by detecting the electric field strength of both a desired signal and an undesired signal as a DC component, a coil adjustment error of an operator's tuner band pass filter or an adjacent signal The set-to-set error of the interference performance of the DTV with respect to the adjacent signal was very severe according to the strength. However, according to the present invention, by operating both the tuner and the IF AGC structure based on a desired signal, the interference performance error of adjacent signals for each set can be minimized.

Claims (2)

A tuner unit for converting a frequency of an input signal into a constant IF frequency and adjusting a signal size according to an input DC component; A first filter unit passing only a specific band of the IF frequency signal converted by the tuner unit; A level detector for detecting a DC level from the output signal from the first filter unit; An intermediate frequency amplifier for amplifying the output signal from the first filter unit based on the level extracted from the level detector unit; A demodulator unit for demodulating the signal amplified by the intermediate frequency amplifier; And a second filter unit which extracts a DC component from an output signal from the demodulator unit and feeds it back to the tuner unit. delete