KR20060130293A - The broadcast receiver and the method of receiving thereof - Google Patents

Abstract

A broadcasting receiving apparatus and a broadcasting receiving method are provided to reduce the noise of the signal amplified by an LNA(Low Noise Amplitude) through the control of sharpness, thereby allowing user to watch the image with excellent quality. An LNA(210) reduces and outputs the noise of the signal received through an antenna(205). A tuner(220) tunes and outputs the desired channel signal among the received signals. A filter(230) passes and outputs only the specific band of the tuned signal. An intermediate frequency signal processing member(240) amplifies and outputs the output signal of the filter. A chroma IC(Integrated Circuit)(280) varies the sharpness of the RGB image signal by the control of a control member(260).

Description

Broadcast receiver and method for receiving broadcast

1 is a block diagram showing the configuration of a conventional broadcast receiving apparatus having a low noise amplifier;

2 is a block diagram showing the configuration of a broadcast receiving apparatus according to the present invention; and

3 is a flowchart provided to explain a broadcast receiving method according to the present invention.

Brief description of the main parts of the drawing

200: broadcast receiving device 205: antenna

210: LNA 220: Tuner

230: filter 240: intermediate frequency signal processing unit

250: AGC unit 260: control unit

270: control switch 280: chroma IC

The present invention relates to a broadcast receiving apparatus and a broadcast receiving method, and more particularly, to a broadcast receiving apparatus and a broadcast receiving method for reducing noise on a screen through sharpness control.

In general, a low noise amplifier (LNA) is a device used in the foremost stage of an RF transceiver of a communication system and requires characteristics such as low noise ratio and high amplification.

1 is a block diagram showing the configuration of a conventional broadcast receiving apparatus having an LNA. Referring to FIG. 1, a conventional broadcast receiving apparatus 100 includes an LNA 10 for reducing noise of a signal received by an antenna 5, and a tuner for tuning a desired channel signal among signals received by the antenna 5. 20, a filter 30 for passing only a specific band of the signals tuned by the tuner 20 and outputting the signal, and an intermediate frequency for amplifying the output signal of the filter 30 around a predetermined intermediate frequency and outputting a video signal. AGC for checking the output signal of the signal processor 40 and the intermediate frequency signal processor 40 and outputting the automatic gain control signals RF-AGC and IF-AGC to the tuner 120 and the intermediate frequency signal processor 40. The unit 50 is switched to the first contact point S1 when the received signal is a weak electric field, and inputs the signal of the antenna to the LNA 10, and is switched to the second contact point S2 when the received signal is a strong electric field. Control switch 70 for inputting a signal to the tuner 120 and a key input or output signal from the AGC unit 50. Check to comprises a control unit 60 for controlling the switching of the control unit 60 and the control switch 70.

That is, the conventional TV receiver 100 installs the LNA 10 having a large noise frequency and a gain in front of the tuner 20 to exclude the loss of the signal generated when the input signal is tuned and to reduce the noise frequency of the entire system. The sensitivity is improved by making it small.

However, since the high frequency signal received by the antenna 5 may be a strong electric field signal or a weak electric field signal, it is necessary to determine whether the input signal is a strong electric field or a weak electric field and perform signal processing according to the result.

 In other words, when the received signal is a weak field signal, the LNA 10 is operated to improve the sensitivity of the system. On the contrary, when the received signal is a strong field signal, the LNA 10 is controlled to not operate. Therefore, when the received signal is a strong electric field, the controller 60 connects the control switch 70 to the second contact point S2 to directly input the signal received by the antenna 5 to the tuner 20, and the received signal is weak. In the case of the electric field signal, the control switch 70 is connected to the first contact point S1 to input the input signal from the antenna to the tuner 20 through the LNA 10.

At this time, the tuner 20 tunes a signal of a desired channel from the high frequency signal directly input from the antenna 5 or amplified by the LNA 10 and outputs the signal to the filter 30. Accordingly, when the filter 30 passes only a signal of a specific band, the intermediate frequency signal processor 40 amplifies a predetermined intermediate frequency and outputs a video signal.

At this time, the AGC unit 50 transmits the automatic gain control signals RF-AGC and IF-AGC generated in response to the level of the video signal output from the intermediate frequency signal processing unit 40 and the tuner 20 and the intermediate frequency signal. The signals are input to the processor 40 and used as signals for controlling gain. Accordingly, the controller 60 controls the control switch 70 by checking the gain control signal from the AGC unit 50 to determine whether the input signal from the antenna 5 is a strong field or a weak field. That is, when it is determined that the received signal is a strong electric field, the control unit 60 connects the control switch 70 to the second contact point S2 so that the received signal is directly input from the antenna 5 to the tuner 20 and is a weak electric field. If it is determined that the control switch 70 is connected to the first contact (S1) so that the received signal is input to the tuner 20 through the LNA 10 to improve the sensitivity.

However, in the conventional TV receiver 100, the LNA 10 has a gain value (RF-AGC) compensated by the AGC unit 50 for the received signal output from the antenna 5 when the received signal is a weak electric field. Add to amplify. In this case, since the noise included in the received signal is also amplified together with the received signal, a lot of noise appears on the screen.

Accordingly, it is an object of the present invention to provide a broadcast receiving apparatus and a broadcast receiving method capable of providing a clearer image by reducing an existing noise component amplified and output from the LNA by adjusting the sharpness of the image.

Broadcast receiving method according to the present invention for achieving the above object comprises the steps of determining the strength of the received signal received through the antenna; If it is determined that the received signal is a weak electric field signal, amplifying the received signal by operating a low noise amplifier, and then outputting the amplified signal; And reducing the sharpness value of the RGB image signal generated based on the amplified signal.

Here, when the strength of the received signal is less than 60dBuV, it is preferable that the received signal is determined as a weak field signal.

Broadcast receiving apparatus according to the present invention comprises a control unit for determining the strength of the received signal received through the antenna; A low noise amplifier for amplifying the received signal and outputting the amplified signal when it is determined that the received signal is a weak electric field signal; And a chroma IC for reducing the sharpness value of the RGB image signal generated based on the amplified signal when it is determined that the received signal is a weak electric field signal.

Here, when the strength of the received signal is less than 60dBuV, it is preferable that the received signal is determined as a weak field signal.

Herein, when the received signal is a weak electric field signal, a control switch for moving the contact point of the switch under the control of the control unit so that the received signal is input to the low noise amplifier, preferably further includes.

2 is a block diagram showing the configuration of a broadcast receiving apparatus according to the present invention. Referring to FIG. 2, the broadcast receiving apparatus 200 includes an LNA 210, a tuner 220, a filter 230, an intermediate frequency signal processor 240, an AGC unit 250, a controller 260, a control switch. 270 and Chroma IC 280.

The LNA 210 reduces the noise of the signal received by the antenna 205 and outputs the tuner 220. The tuner 220 tunes and outputs a desired channel signal among the signals received by the antenna 205. The filter 230 passes through only a specific band among the signals tuned by the tuner 220 and outputs the signal. The intermediate frequency signal processor 240 amplifies and outputs the output signal of the filter 230 about a predetermined intermediate frequency.

The chroma IC 280 varies the sharpness value of the RGB image signal generated from the signal output from the intermediate frequency signal processor 240 under the control of the controller 260. In particular, in the preferred embodiment of the present invention, the chroma IC 280 reduces the sharpness value of the RGB image signal by the control of the controller 260.

 The AGC unit 250 checks the output signal of the intermediate frequency signal processor 240 and outputs the automatic gain control signals RF-AGC and IF-AGC to the tuner 220 and the intermediate frequency signal processor 240.

The control switch 270 is switched to the first contact point S1 when the signal received by the control of the controller 260 is a weak electric field to input the signal of the antenna 205 to the LNA 210, and the received signal is a strong electric field. In this case, the signal is switched to the second contact point S2 to input the signal of the antenna 205 to the tuner 220.

The controller 260 controls the switching of the controller 260 and the control switch 270 by checking a key input of the user or an output signal of the AGC unit 250. More specifically, the control unit 260 determines the strength of the received signal, and operates the LNA 210 when the received signal is a weak electric field signal to improve the sensitivity of the system, and conversely, when the received signal is a strong field signal, the LNA 210. ) Is not operated. Therefore, when the received signal is a strong electric field, the controller 260 connects the control switch 270 to the second contact point S2 to directly input the signal received by the antenna 205 to the tuner 220, and the received signal is weak. In the case of the electric field signal, the control switch 270 is connected to the first contact point S1 to input the input signal from the antenna 205 to the tuner 220 through the LNA 210. The controller 260 controls the control switch 270 by checking the gain control signal output from the AGC unit 250 to determine whether the input signal from the antenna 205 is a strong field or a weak field. That is, when it is determined that the received signal is a strong electric field, the control unit 260 connects the control switch 270 to the second contact point S2 so that the received signal is directly input from the antenna 205 to the tuner 220 and is a weak electric field. If it is determined that the control switch 270 is connected to the first contact (S1) so that the received signal is input to the tuner 220 through the LNA 210 to improve the sensitivity.

3 is a flowchart provided to explain a broadcast receiving method according to the present invention.

Referring to FIG. 3, first, the controller 260 determines the strength of a received signal input to the antenna 205 (S310). At this time, the controller 260 determines the strength of the received signal input to the antenna 205 based on a result of comparing the automatic gain control signal provided from the AGC unit 250 with a predetermined threshold value. That is, when the magnitude of the automatic gain control signal provided from the AGC unit 205 is larger than a predetermined threshold value, the controller 260 determines that the received signal is a weak electric field. At this time, when the received signal is determined to be a weak electric field, the strength of the received signal is less than approximately 60 dBuV. In addition, when the magnitude of the automatic gain control signal provided from the AGC unit 205 is smaller than a predetermined threshold value, the controller 260 determines that the received signal is a strong electric field. At this time, when the received signal is determined to be a strong electric field, the strength of the received signal is greater than approximately 60 dBuV.

If it is determined that the received signal is a weak electric field (S320: Y), the controller 260 controls the LNA 210 to operate (S330). That is, the controller 260 connects the control switch 270 to the first contact point S1 so that the received signal is amplified through the LNA 210. At this time, the amplified noise is also present in the signal amplified and output from the LNA (210).

Subsequently, the controller 260 controls the chroma IC 280 so as to reduce the sharpness value of the RGB image signal to a predetermined value (S340). As such, when the sharpness value of the RGB video signal is decreased, when the received signal is a weak signal, the noise present in the signal amplified by the LNA 210 and displayed is weakly seen on the screen, so that the user can view the optimal screen. Will be.

On the other hand, if it is determined that the received signal is a strong electric field (S320: N), the control unit 260 controls so that the LNA 210 is not operated (S350). That is, the controller 260 controls the control switch 270 to be connected to the second contact point S2 so that the received signal is input to the tuner 220. Since this is not related to the main technical features of the present invention, a detailed description thereof will be omitted.

As described above, according to the present invention, by reducing the noise present in the signal amplified by the LNA through the sharpness control, there is an advantage that allows the user to watch a clearer image.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the present invention is not limited to the specific embodiments of the present invention without departing from the spirit of the present invention as claimed in the claims. Anyone skilled in the art can make various modifications, as well as such modifications that fall within the scope of the claims.

Claims (5)

Determining the strength of a received signal received through the antenna; If it is determined that the received signal is a weak electric field signal, operating the low noise amplifier to amplify the received signal and outputting the amplified signal; And And reducing the sharpness value of the RGB video signal generated based on the amplified signal. The method of claim 1, When the strength of the received signal is less than 60dBuV, And the received signal is determined as a weak electric field signal. A control unit to determine the strength of the received signal received through the antenna; A low noise amplifier for amplifying the received signal and outputting the amplified signal when it is determined that the received signal is a weak electric field signal; And And a chroma IC for reducing the sharpness value of the RGB image signal generated based on the amplified signal when it is determined that the received signal is a weak electric field signal. The method of claim 3, When the strength of the received signal is less than 60dBuV, And the received signal is determined as a weak electric field signal. The method of claim 3, And a control switch for moving the contact point of the switch under the control of the control unit so that the received signal is input to the low noise amplifier, when the received signal is a weak electric field signal.

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