KR20040082036A - Broadcast signal receiver and method for controlling signal power of the same - Google Patents

Abstract

PURPOSE: An apparatus for receiving a broadcasting signal and a method for controlling signal strength thereof are provided to periodically check the strength of an input signal and maintain an optimal receiving state through the control of an RF(Radio Frequency) splitter having an RF gain controller. CONSTITUTION: An RF splitter(21) determines a compensation level by an RF_Splitter_AGC(Automatic Gain Control) signal. A tuner(22) tunes a signal outputted from the RF splitter, and compensates signal strength according to a different amplification level by an RF_Tuner_AGC signal. A SAW(Surface Acoustic Wave) filter(23) filters the tuned signal, and removes noise. A down-converter(24) converts the filtered signal into a low-frequency signal, and compensates the signal strength according to a different amplification level by an IF_AGC signal. A VSB(Vestigial SideBand) decoder(25) performs the VSB decoding of the signal outputted from the down-converter, and outputs VSB data, the IF_AGC signal and the RF_Tuner_AGC signal. A CPU(26) outputs the RF_Splitter_AGC signal on the basis of an SNR(Signal to Noise Ratio) read in the VSB decoder.

Description

Broadcast signal receiver and method for controlling signal strength thereof {Broadcast signal receiver and method for controlling signal power of the same}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a broadcast receiver, and more particularly, to a broadcast signal receiving apparatus and a method for controlling signal strength thereof, by periodically checking the strength of an input signal to maintain an optimal reception state by controlling an RF splitter having an RF gain controller It is about.

Currently, many transceivers using RF have been produced. The original signal input to the receiver may continuously change in size depending on the state of the transmission medium.

Therefore, there is a great need for maintaining an optimal reception state despite the magnitude of the continuously changing signal. These transceivers use RF splitters that can send and receive two or more original signals.

Hereinafter, a broadcast signal receiving apparatus according to the related art will be described with reference to the accompanying drawings.

1 is a block diagram illustrating a broadcast signal receiver of the prior art.

In the prior art, an AGC (Auto Gain Controller) is used in the tuner unit and the IF signal processing unit to compensate for a signal caused by a change in the input signal strength in an HDTV or a set top box.

The configuration includes an RF splitter 11 for distributing the received signal to two or more receiving devices, a tuner 12 for tuning the signal output to the RF splitter 11 and demodulating the signal into an intermediate frequency band, and tuning. A surface acoustic wave (SAW) filter 13 for filtering out the filtered signal to remove noise, a down converter 14 for converting the filtered signal into a low frequency signal, and a signal output from the down converter 14 and a VSB demodulator 15 for outputting VSB data by decoding (vestigial sideband), outputting an IF AGC signal to the down converter 14, and outputting an RF AGC signal to the tuner 12.

Such a broadcast signal receiver of the prior art can operate well without any problem when the received signal is good, but the power of the received signal is weak, such as when watching using an indoor antenna, and indoors, such as a person or an animal. In an environment where there are many disturbances in signals received by the movement of the camera, it cannot be effectively coped with.

In addition, the conventional reception method may be limited by the RF amplification degree in the tuner 12 and the IF amplification degree in the IF processing stage. In addition, a method of compensating the amplification degree in the RF splitter 11 as much as the attenuation of the input original signal is used.

However, the conventional broadcast signal receiving apparatus described above has the following problems.

RF splitters used in the prior art cause a phenomenon of reducing the magnitude of the original signal. Therefore, a method of processing a signal by compensating attenuation of the original signal by amplifying the signal is used for processing the signal.

This method is very difficult to process when the original signal is very weak, or when the magnitude of the input signal is very different according to the place, and the compensation of the signal attenuation according to each other case is wrong.

In addition, when a weak error occurs due to a change in the received signal, an error may occur because of late handling.

The present invention is to solve the problems of the conventional broadcast signal receiving apparatus as described above, by periodically checking the strength of the input signal to maintain an optimal reception state through the control of the RF splitter having an RF gain controller An object of the present invention is to provide a broadcast signal receiving apparatus and a method of controlling signal strength thereof.

1 is a block diagram illustrating a conventional broadcast signal receiver

2 is a block diagram of a broadcast signal receiving apparatus according to the present invention

3 is an AGC value setting table of an RF splitter

4A and 4B are flowcharts for controlling broadcast signal reception signal strength according to the present invention.

Explanation of symbols for main parts of the drawings

21.RF Splitter 22. Tuner

23. SAW filter 24. Down converter

25.VSB Demodulator 26.CPU

The broadcast signal receiving apparatus according to the present invention for achieving the above object is an RF splitter whose compensation magnitude is determined by an RF splitter AGC (RF_Splitter_AGC) signal; tuning the signal output from the RF splitter and RF tuner AGC (RF_Tuner_AGC) signal A tuner that compensates for signal strength by varying the amplitude of the amplified signal; a SAW filter that filters the filtered signal to remove noise; converts the filtered signal into a low frequency signal and varies the amplitude of the amplified signal by the IF AGC signal IF_AGC A down converter for compensating signal strength of the down converter; VSB decoding a signal output from the down converter to output VSB data, and output an IF AGC signal and an RF tuner AGC signal; based on a signal-to-noise ratio (SNR) read from the VSB demodulator. And a CPU for outputting an RF splitter AGC (RF_Splitter_AGC) signal.

In the signal strength control method of the broadcast signal receiving apparatus for achieving the object according to the present invention, the step of comparing the SNR value and the set optimal signal strength value (Threshold) is repeated, and if the comparison result set value is large, the comparison step is repeated. Determining whether the compensation magnitudes of the RF_Tuner_AGC signal and the IF_AGC signal are sequentially within the set range each time; If it is determined that the compensation magnitudes of the RF_Tuner_AGC signal and the IF_AGC signal are not within the setting range, the signal strength is compensated by the difference obtained by subtracting the threshold from the SNR value by comparing the strength of the input signal with the strength of the output signal. And outputting an RF_Splitter_AGC signal.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of the embodiments.

A preferred embodiment of the apparatus for receiving broadcast signals and the method of controlling signal strength thereof according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a broadcast signal receiving apparatus according to the present invention, and FIG. 3 is an AGC value setting table of an RF splitter.

The present invention uses an RF splitter having a gain controller to periodically check an input signal whose reception intensity of a broadcast signal is changed, and adjusts amplification degree programmatically according to the strength of an input signal. It is to keep the reception state.

The present invention is naturally applicable to all transceivers using the RF splitter, in particular, TVs and set-top boxes that receive HD video signals.

The configuration divides the received signal to two or more receiving devices as shown in FIG. 2, and when the RF splitter AGC (RF_Splitter_AGC) signal is input, the RF splitter 21 whose compensation magnitude is determined by a predetermined amplification level table. And a tuner 22 that tunes the signal output from the RF splitter 21 to demodulate the signal into an intermediate frequency band and compensates the signal strength by varying the amplitude of the amplification by an RF tuner AGC (RF_Tuner_AGC) signal. Surface acoustic wave (SAW) filter 23 to filter out the signal to remove noise, and down to convert the filtered signal into a low frequency signal and compensate the signal strength by varying the amplitude of the amplification by the IF AGC signal IF_AGC. A converter 24 and a vestigial sideband (VSB) decoded signal output from the down converter 24 output VSB data, output an IF AGC signal to the down converter 24, and output an RF tuner AGC signal. RF splitter AGC (RF_Splitter_AGC) for controlling the compensation magnitude of the RF splitter 21 based on the VSB demodulator 25 outputted to you 22 and the Signal to Noise Ratio (SNR) read by the VSB demodulator 25. CPU 26 for outputting the signal.

As described above, the present invention compensates for the variation in the case where an error occurs due to a change in the input signal strength, and checks the strength of the received signal periodically by the tuner and the IF processing stage. The RF splitter stage with the controller compensates for the optimal received signal strength.

First, the input signal is compensated for the appropriate signal size in the process of processing the RF_Tuner_AGC, IF_AGC signal output from the VSB demodulator, there is a limit to such compensation.

Therefore, the RF splitter 21 further improves this limit, and the compensation magnitude of the signal is determined by a predetermined amplification level table as shown in FIG. 3 by the RF_Splitter_AGC signal.

The intensity of the input signal may change from time to time according to the transmission medium of the input signal. Therefore, the broadcast signal receiving apparatus of the present invention periodically checks and compensates for the strength of the input signal in order to overcome this limitation of compensation while maintaining proper reception performance.

The amplification by the RF_Splitter_AGC signal is applied when the SNR read by the VSB demodulator 25 is bad after the compensation by the RF_Tuner_AGC or IF_AGC is applied first.

Referring to the method of controlling the signal strength according to the present invention in detail.

4A and 4B are flowcharts for controlling broadcast signal reception signal strength according to the present invention.

The SNR is periodically checked to compensate for the RF_Splitter_AGC signal by the difference with the size (here, Threshold) set as the optimal signal strength.

First, the SNR value read from the VSB demodulator is compared with the set optimal signal strength (S401).

If the SNR value is large, after the set input signal check period (Input_Signal_Check_Time) has passed (S410), the SNR value is again compared with the set optimal signal strength (S411).

If the SNR value is small, it is determined whether the compensation magnitude of the RF_Tuner_AGC signal is within the set value (S402).

If the compensation magnitude of the RF_Tuner_AGC signal is within the set value, the SNR value is again compared with the set optimal signal strength (S409), and after the set input signal check period (Input_Signal_Check_Time) has passed (S410), the SNR value and the set optimal value are again set. The signal strength is compared (S411).

If the compensation magnitude of the RF_Tuner_AGC signal is not within the set value, the SNR value is compared with the set optimal signal strength (S403). If the SNR value is small, it is determined whether the compensation magnitude of the IF_AGC signal is within the set value (S404). )

If the compensation amplitude of the IF_AGC signal is within the set value, the SNR value is again compared with the set optimal signal strength (S409), and after the set input signal check period (Input_Signal_Check_Time) has passed (S410), the SNR value and the set optimal value are again set. The signal strength is compared (S411).

If the SNR value is not good even when the compensation is performed by the RF_Tuner_AGC signal and the IF_AGC signal by this step, the strength of the input signal and the DTV power (output signal strength) are compared (S406).

As a result of the comparison, in the case of the weak electric field, the RF_Splitter_AGC signal is output to compensate for the difference by subtracting the set value (Threshold) from the SNR value by setting the electric field flag to 0 (ElecField_Flag = 0) (S407).

As a result of the comparison, in the case of a strong electric field, the RF_Splitter_AGC signal is output to compensate for the negative compensation by the difference obtained by subtracting the set value (Threshold) from the SNR value by setting the electric field flag to 1 (ElecField_Flag = 1) (S408).

Of course, even after the RF_Splitter_AGC signal is output and compensated, the SNR value is again compared with the set optimal signal strength (S409), and after the set input signal check period (Input_Signal_Check_Time) has passed (S410), the SNR value is again compared with the SNR value. The set optimal signal strength is compared (S411).

The signal strength compensation as described above compensates for each set input signal check period (Input_Signal_Check_Time), but is usually set in units of several tens of seconds.

The RF_Splitter_AGC signal may give a level of compensation by the number of combinations according to the number of bits. The number of combinations required may vary as required by the user.

That is, more bits can be allocated for fine tuning.

For example, if you table the value of RF_Splitter_AGC in 3 bits as the number of cases, the table value that corresponds to the amplification degree is given as RF_Splitter_AGC value in the table according to the 8 states combined by this 3 bit, and the gain controller in the RF splitter You will compensate by the values in the table.

The compensation routine by the RF_Splitter_AGC signal keeps trying until the VSB_Error does not occur. Even when there is no VSB Error, the compensation routine is checked periodically and adjusted to the optimum strength so that the VSB Error does not occur in advance.

The method of controlling the signal strength according to the present invention periodically checks the SNR by the input signal, checks whether the received signal strength is set to an optimal value, and continuously compensates for the difference magnitude.

The broadcast signal receiving apparatus and the signal strength control method thereof according to the present invention have the following effects.

First, the present invention can raise the limit of signal attenuation compensation by gain control in the tuner and the IF processor in the video device for HDTV reception.

Second, by checking the strength of the received signal periodically to compensate for the appropriate signal strength, error occurrence due to the signal strength is suppressed.

Third, there is an effect of providing an optimal reception environment to the user by checking and compensating periodic signal strength.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (9)

An RF splitter whose compensation magnitude is determined by an RF splitter AGC (RF_Splitter_AGC) signal; A tuner for tuning the signal output from the RF splitter and compensating for signal strength by varying the amplitude of the amplification by an RF tuner AGC (RF_Tuner_AGC) signal; A SAW filter for filtering out the tuned signal to remove noise; A down converter converting the filtered signal into a low frequency signal and compensating for signal strength by varying the amplitude of the amplification by the IF AGC signal IF_AGC; A VSB demodulator for VSB decoding a signal output from the down converter to output VSB data and to output an IF AGC signal and an RF tuner AGC signal; And a CPU for outputting an RF splitter AGC (RF_Splitter_AGC) signal based on a signal-to-noise ratio (SNR) read from a VSB demodulator. The apparatus of claim 1, wherein the RF splitter includes a programmable gain controller and a compensation magnitude is determined by a predetermined amplification level table when an RF splitter AGC (RF_Splitter_AGC) signal is input. 2. The RF splitter of claim 1, wherein the RF splitter compensates the signal strength by comparing the signal-to-noise ratio (SNR) read in the state where signal strength compensation is performed by the IF AGC signal and the RF tuner AGC signal with a set optimal signal strength value. Broadcast signal receiving apparatus. Repeat the step of comparing the SNR value and the set optimal signal strength value (Threshold), and if the comparison result is large, Determining whether the compensation magnitudes of the RF_Tuner_AGC signal and the IF_AGC signal are sequentially within the set range each time the comparison step is repeated; If it is determined that the compensation magnitudes of the RF_Tuner_AGC signal and the IF_AGC signal are not within the set range, And outputting an RF_Splitter_AGC signal to compensate the signal strength by a magnitude obtained by subtracting a threshold from the SNR value by comparing the strength of the input signal with the strength of the output signal. Signal strength control method. 5. The method of claim 4, wherein the strength of the input signal is compared with the strength of the output signal. In the case of a weak electric field, the electric field flag is set to 0 (ElecField_Flag = 0) to compensate for the difference obtained by subtracting the threshold from the SNR value. And outputting an RF_Splitter_AGC signal to compensate for the signal strength. 5. The method of claim 4, wherein the strength of the input signal is compared with the strength of the output signal, and in the case of a strong electric field, the electric field flag is set to 1 (ElecField_Flag = 1) to compensate for the difference by subtracting the set value (Threshold) from the SNR value. And outputting an RF_Splitter_AGC signal to compensate for the signal strength. The method of claim 4, further comprising comparing the SNR value with a set optimal signal strength value. A method of controlling the signal strength of a broadcast signal receiving apparatus, characterized by repeating on the basis of a set input signal check period (Input_Signal_Check_Time). The method of claim 4, even after outputting an RF_Splitter_AGC signal to compensate for signal strength, Comparing the SNR value and the set optimal signal strength (Threshold) and the signal strength compensation step by the RF_Splitter_AGC signal output repeats until the set optimal signal strength (Threshold) is smaller than the SNR value Signal strength control method. The signal strength of the broadcast signal receiving apparatus according to claim 4, wherein the RF_Tuner_AGC signal is a signal for adjusting the amplification level in the tuner, and the IF_AGC signal is a signal for adjusting the amplification level in the down converter after SAW filtering. Control method.