KR100714556B1 - Television receiver with improved audio and video - Google Patents

Abstract

SUMMARY OF THE INVENTION An object of the present invention is to provide a TV receiver having an improved A / V separation function implemented to separate audio signals A and video signals V with good quality in correspondence with the PAL and SECAM schemes, respectively.

A television receiver having a video signal distortion correction function according to the present invention includes: an adjacent trap circuit unit for trapping adjacent audio intermediate frequencies included in an input intermediate frequency; A first audio filter for passing a first voice intermediate frequency of a first broadcast method among intermediate frequencies through the adjacent trap circuit unit; The passband is variably set according to a band variable control signal, and the set passband selectively selects a first video intermediate frequency of a first broadcast method or a second video intermediate frequency of a second broadcast method from among intermediate frequencies through the adjacent trap circuit unit. A video filter to pass through; A bypass circuit unit for bypassing the intermediate frequency at an input of the adjacent trap circuit unit; And a second audio filter unit for passing a second voice intermediate frequency of a second broadcast method among the intermediate frequencies through the bypass circuit unit.

TV reception, video signal, distortion correction, adjacent channel trap, PAL, SECAM

Description

TV receiver with improved A / B separation function {TELEVISION RECEIVER WITH IMPROVED AUDIO AND VIDEO}

1 is a block diagram of a conventional TV receiver.

2 (a) and 2 (b) are IF frequency spectrum diagrams according to broadcasting methods in a conventional TV receiver.

3 is a block diagram of a TV receiver according to the present invention;

Figure 4 (a) and (b) is a IF frequency spectrum diagram according to the broadcasting method in the TV receiver of the present invention.

Explanation of symbols on the main parts of the drawings

100: adjacent trap circuit portion 200: SAW filter

210: first audio filter unit 220: video filter unit

300: bypass circuit unit 400: second audio filter unit

500: IF circuit part SC: band variable control signal

IF: intermediate frequency SIF-A; Adjacent Voice Intermediate Frequency

SIF1: first voice intermediate frequency SIF2: second voice intermediate frequency

PIF1: first video intermediate frequency PIF2: second video intermediate frequency

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a TV receiver applied to a TV set, a VTR, and the like. Particularly, the present invention implements the audio signal A and the video signal V to be separated from each other with good quality in correspondence with the PAL method and the SECAM method, respectively. The present invention relates to a TV receiver having an improved A / V separation function capable of providing a video signal having excellent adjacent channel rejection characteristics and providing a more stable audio signal without the influence of adjacent channel traps in the SECAM scheme.

In general, television systems are classified into NTSC, PAL, and SECAM systems. Among these broadcasting systems, PAL and SECAM systems have differences in many specifications. PAL is 5.5 MHz and SECAM is 5.5 MHz or 6.5 MHz. The video intermediate frequency (PIF) is 38.9 MHz for the PAL method, 33.9 MHz for the SECAM, and the audio intermediate frequency (SIF) is 33.4 MHz for the PAL, and 40.4 MHz for the SECAM.

As described above, since the PAL and SECAM systems have different video intermediate frequencies and audio intermediate frequencies, the TV receiver is a circuit for separating and passing the video intermediate frequencies and the audio intermediate frequencies for each broadcasting system. Need.

1 is a block diagram of a conventional TV receiver.

The conventional TV receiver shown in FIG. 1 includes an adjacent trap circuit unit 10 for trapping adjacent channels included in an input intermediate frequency IF, and an image intermediate of an intermediate frequency IF from the adjacent trap circuit unit 10. SAW filter unit 20 for separating the frequency PIF and the audio intermediate frequency SIF separately, and IF demodulating the video intermediate frequency PIF and the audio intermediate frequency SIF from the SAW filter unit 20. The circuit unit 500 is included.

The SAW filter unit 20 includes a first audio filter unit 21A which passes a first voice intermediate frequency SIF1 of the PAL method among the intermediate frequencies IF from the adjacent trap circuit unit 10, and the adjacent unit. And a video SAW filter 21 including a video filter unit 21B for selectively passing the PAL or SECAM image intermediate frequencies PIF1 and PIF2 among the intermediate frequencies IF from the trap circuit unit 10. .

In addition, the SAW filter unit 20 includes an audio SAW filter 22 for passing a second voice intermediate frequency SIF2 of the SECAM method among the intermediate frequencies IF from the adjacent trap circuit unit 10.

Here, the video filter unit 21B has a passband that is varied according to a band variable control signal SC according to a broadcast method, passes the first video intermediate frequency PIF1 in the PAL method, and a second video in the SECAM method. Pass the intermediate frequency (PIF2).

2 (a) and 2 (b) are IF frequency spectrum diagrams of broadcasting methods in a conventional TV receiver.

Referring to (a) of FIG. 2, the separation and the path of the audio intermediate frequency and the video intermediate frequency in the case of the PAL method will be described. 33.4MHz, which is the first voice intermediate frequency (SIF1) of the PAL method, is the first audio signal. 38.9 MHz, which is passed by the filter unit 21A, and the first image intermediate frequency PIF1 of the PAL method, is passed by the video filter unit 21B.

Referring to (b) of FIG. 2, the separation and the path of the audio intermediate frequency and the video intermediate frequency in the case of the SECAM method are described. The second audio intermediate frequency (SIF2) of 40.4MHz is the second audio. Passed by the SAW filter 22, 33.9MHz, the second video intermediate frequency PIF2 of the SECAM method, is passed by the video filter 21B.

In the conventional TV receiver, however, in the SECAM method, 40.4 MHz, which is the second voice intermediate frequency SIF2, is trapped by the adjacent trap circuit unit 10 and the second voice intermediate frequency is distorted. There is a problem that the quality of the voice signal in the SECAM method is significantly lowered.

SUMMARY OF THE INVENTION The present invention has been proposed to solve the above problems, and an object thereof is to provide an audio signal (A) and a video signal (V) for a TV set, a VTR, and the like. By separating each other with quality, it is possible to provide a video signal having excellent adjacent channel rejection characteristics for each broadcast, and A / V separation function that can provide more stable audio signal without influence of adjacent channel trap in SECAM method. To provide an improved TV receiver.

In order to achieve the above object of the present invention, the TV receiver with improved A / V separation function of the present invention, the adjacent trap circuit unit for trapping the adjacent audio intermediate frequency contained in the input intermediate frequency; A first audio filter for passing a first voice intermediate frequency of a first broadcast method among intermediate frequencies through the adjacent trap circuit unit; A passband is variably set according to a band variable control signal, and the set passband is a first video intermediate frequency of a first broadcast method or a second video intermediate frequency of a second broadcast method among the intermediate frequencies through the adjacent trap circuit unit. A video filter unit for selectively passing; A bypass circuit unit for bypassing the intermediate frequency at an input of the adjacent trap circuit unit; And a second audio filter unit for passing a second voice intermediate frequency of a second broadcast method among the intermediate frequencies through the bypass circuit unit.

The TV receiver outputs a band variable control signal according to a first broadcast method or a second broadcast method to the video filter unit, demodulates the first audio and first video intermediate frequencies when the first broadcast method is selected, The second broadcasting method may further include an IF circuit unit for demodulating the second audio and second video intermediate frequencies.

The first broadcast method is a PAL method, and the second broadcast method is a SECAM method.

The adjacent voice intermediate frequency is approximately 40.4 MHz, and the first audio filter portion is formed with a pass band of approximately 33.4 MHz, and the video filter portion has a pass band of approximately 38.9 MHz or 33.9 MHz according to the band variable control signal. The second audio filter unit is configured by setting the pass band at approximately 40.4 MHz.

The bypass circuit unit may include a capacitor connected between an input terminal of the adjacent trap circuit unit and the second audio filter unit.

The first audio filter unit and the video filter unit may be implemented as one SAW filter.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings referred to in the present invention, components having substantially the same configuration and function will use the same reference numerals.

3 is a block diagram of a TV receiver according to the present invention.

Referring to FIG. 3, the TV receiver according to the present invention includes an adjacent trap circuit unit 100 for trapping an adjacent voice intermediate frequency SIF-A included in an input intermediate frequency IF, and the adjacent trap circuit unit 100. The passband is variably set according to the first audio filter unit 210 for passing the first voice intermediate frequency SIF1 of the first broadcasting method and the band variable control signal SC. In the set pass band, the first video intermediate frequency PIF1 of the first broadcast method or the second video intermediate frequency PIF2 of the second broadcast method among the intermediate frequencies IF through the adjacent trap circuit unit 100. Through the video filter unit 220 to selectively pass through, the bypass circuit unit 300 for bypassing the intermediate frequency IF at the input terminal of the adjacent trap circuit unit 100, and the bypass circuit unit 300 The second voice intermediate frequency of the second broadcasting method in the intermediate frequency IF And a second audio filter 400 passing through SIF2.

The TV receiver outputs a band variable control signal SC according to selection of a first broadcast method or a second broadcast method to the video filter unit 220, and when the first broadcast method is selected, the first voice and the first broadcast method. The apparatus further includes an IF circuit unit 500 for demodulating the video intermediate frequencies SIF1 and PIF1 and demodulating the second audio and the second video intermediate frequencies SIF2 and PIF2 when the second broadcast method is selected. Here, the first broadcast method is a PAL method, and the second broadcast method is a SECAM method.

In addition, the adjacent voice intermediate frequency (SIF-A) is the adjacent voice intermediate frequency of the PAL method and corresponds to approximately 40.4 MHz.

The first audio filter unit 210 has a passband set to approximately 33.4 MHz corresponding to a PAL voice intermediate frequency. The video filter unit 220 has a passband set to approximately 38.9 MHz corresponding to the PAL video intermediate frequency or 33.9 MHz corresponding to the SECAM video intermediate frequency according to the band variable control signal SC. Is done. The second audio filter unit 400 has a passband set to approximately 40.4 MHz corresponding to a voice intermediate frequency of the SECAM method.

The bypass circuit unit 300 includes a capacitor connected between the input terminal of the adjacent trap circuit unit 100 and the second audio filter unit 400.

The first audio filter 210 and the video filter 220 may be implemented as one SAW filter 200.

4 (a) and 4 (b) are IF frequency spectrum diagrams of broadcasting methods according to a TV receiver of the present invention.

In FIG. 4A, SIF1 corresponds to a voice intermediate frequency in the PAL method, which is passed by the first audio filter 210. PIF1 corresponds to the image intermediate frequency in the SECAM method, which is passed by the video filter unit 220. SIF-A corresponds to the adjacent voice intermediate frequency in the PAL method, which is removed by the adjacent trap circuit unit 100.

In FIG. 4B, PIF2 corresponds to an image intermediate frequency in the SECAM scheme, which is passed by the video filter unit 220. SIF2 corresponds to the voice intermediate frequency in the SECAM method, which is passed by the second audio filter unit 400.

Hereinafter, the operation and effects of the present invention will be described in detail with reference to the accompanying drawings.

The TV receiver of the present invention separates the audio intermediate frequency and the image intermediate frequency of the selected broadcasting system from the tuner unit and the IF circuit unit to maintain a good quality between the tuner unit and the IF circuit unit to selectively view the PAL or SECAM system among the TV broadcasting systems. Pass through the channel so that each broadcast can be viewed with good quality.

In the TV receiver of the present invention, an operation when selecting a PAL method and an operation when selecting a SECAM method will be described, respectively.

First, the operation of the TV receiver of the present invention when selecting the PAL method will be described.

3 and 4, when the PAL method is selected, when the band variable control signal SC is provided to the video filter unit 220 of the SAW filter 200, the video filter unit 220 may change the band variable. A passband of 38.9 MHz corresponding to the first image intermediate frequency PIF1 of the PAL method is set according to the control signal SC. The band variable control signal SC may be provided through the IF circuit unit 500.

In this case, the adjacent trap circuit unit 100 of the TV receiver of the present invention removes 40.4 MHz, which is the adjacent voice intermediate frequency (SIF-A) of the PAL method, included in the intermediate frequency (IF) from the tuner unit. )

The video filter unit 220 of the SAW filter 200 passes 38.9 MHz, which is the first image intermediate frequency PIF1, among the intermediate frequencies IF from the adjacent trap circuit unit 100, through the set pass band, and the IF passes through the IF band. Output to the circuit unit 500.

In addition, the first audio filter unit 210 passes the 33.4 MHz first audio intermediate frequency SIF1 of the first broadcasting method among the intermediate frequencies IF through the adjacent trap circuit unit 100 and passes the IF circuit unit. Output as 500.

In this case, the IF circuit unit 500 includes 38.9 MHz, which is the first image intermediate frequency PIF1 from the video filter unit 220, and a first audio intermediate frequency SIF1, which is generated from the first audio filter unit 210. 33.4MHz, respectively, are used to provide a baseband audio signal and a video signal.

Through this operation, in the TV receiver of the present invention, when PAL is selected, 33.4 MHz, which is the voice intermediate frequency from which 40.4 MHz of the adjacent voice frequency is removed, and 38.9 MHz, which is the image intermediate frequency, are separated from each other and provided to the IF circuit unit. Therefore, by using the TV receiver of the present invention, it is possible to watch good PAL broadcasts.

Next, the operation of the TV receiver of the present invention when selecting the SECAM method will be described.

3 and 4, when the SECAM scheme is selected, when the band variable control signal SC is provided to the video filter unit 220 of the SAW filter 200, the video filter unit 220 may perform the band variable. A passband of 33.9 MHz corresponding to the second video intermediate frequency PIF2 of the SECAM method is set according to the control signal SC.

In this case, the adjacent trap circuit unit 100 of the TV receiver of the present invention removes 40.4 MHz, which is the adjacent voice intermediate frequency (SIF-A) of the PAL method, included in the intermediate frequency (IF) from the tuner unit. )

The video filter unit 220 of the SAW filter 200 passes 33.9 MHz, which is a second image intermediate frequency PIF2, among the intermediate frequencies IF from the adjacent trap circuit unit 100, through the set pass band. Output to the circuit unit 500.

Meanwhile, the bypass circuit unit 300 of the present invention bypasses the intermediate frequency IF to the second audio filter unit 400 at the input terminal of the adjacent trap circuit unit 100.

In this case, the second audio filter unit 400 passes the 40.4 MHz second voice intermediate frequency SIF2 of the SECAM method among the intermediate frequencies IF through the bypass circuit unit 300 and passes the IF circuit unit 500. )

In this case, the IF circuit unit 500 is 33.9 MHz, which is the second image intermediate frequency PIF1 from the video filter unit 220, and the second audio intermediate frequency SIF2, which is generated from the second audio filter unit 400. 40.4MHz are demodulated to provide a baseband audio signal and a video signal of the SECAM broadcasting method.

Through this operation, in the TV receiver of the present invention, when SECAM is selected, a good SECAM broadcast can be watched by separating the voice intermediate frequency 40.4MHz and the video intermediate frequency 33.9MHz to the IF circuit unit.

According to the present invention as described above, when selecting a PAL broadcast method or SECAM broadcast method, the audio and video intermediate frequencies for the selected broadcast method can be satisfactorily separated without providing a special level reduction, thereby providing high quality PAL broadcast or SECAM broadcast. To watch.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, but is defined by the claims, and the apparatus of the present invention may be substituted, modified, and modified in various ways without departing from the spirit of the present invention. It is apparent to those skilled in the art that modifications are possible.

According to the present invention as described above, in the TV receiver applied to the TV set, VTR, etc., by implementing the audio signal (A) and the video signal (V) to be separated from each other with good quality corresponding to each of the PAL method and SECAM method, Each broadcast can provide a video signal having excellent adjacent channel rejection characteristics, and can provide a more stable audio signal without the influence of adjacent channel traps in the SECAM scheme.

Claims (9)

An adjacent trap circuit unit for trapping adjacent voice intermediate frequencies included in the input intermediate frequency; A first audio filter for passing a first voice intermediate frequency of a first broadcast method among intermediate frequencies through the adjacent trap circuit unit; A passband is variably set according to a band variable control signal, and the set passband is a first video intermediate frequency of a first broadcast method or a second video intermediate frequency of a second broadcast method among the intermediate frequencies through the adjacent trap circuit unit. A video filter unit for selectively passing; A bypass circuit unit for bypassing the intermediate frequency at an input of the adjacent trap circuit unit; And A second audio filter unit for passing a second voice intermediate frequency of a second broadcast method among intermediate frequencies through the bypass circuit unit TV receiver having a video signal distortion correction function comprising a. The method of claim 1, wherein the TV receiver, Outputs a band-variable control signal according to a first broadcast method or a second broadcast method to the video filter unit, and when selecting a first broadcast method, demodulates the first audio and first video intermediate frequencies, and selects a second broadcast method. The IF circuit section demodulates the second audio and second video intermediate frequencies. TV receiver having a video signal distortion correction function further comprising. The method of claim 2, wherein the first broadcast method PAL method, The second broadcast method TV receiver having a video signal distortion correction function, characterized in that the SECAM method. The method of claim 3, wherein the adjacent voice intermediate frequency TV receiver having a video signal distortion correction function, characterized in that about 40.4MHz. The method of claim 3, wherein the first audio filter unit A TV receiver having a video signal distortion correction function, characterized in that the pass band is set to approximately 33.4 MHz. The method of claim 3, wherein the video filter unit And a pass band of approximately 38.9 MHz or 33.9 MHz, respectively, according to the band variable control signal. The method of claim 3, wherein the second audio filter unit The TV receiver having a video signal distortion correction function, characterized in that the pass band is set to approximately 40.4MHz. The method of claim 1, wherein the bypass circuit unit, And a capacitor connected between an input terminal of the adjacent trap circuit unit and the second audio filter unit. The method of claim 1, wherein the first audio filter unit and the video filter unit TV receiver having a video signal distortion correction function, characterized in that implemented by one SAW filter.

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