KR100301516B1 - Apparatus for optimum adjusting screen position of digital television - Google Patents

Abstract

The present invention relates to an apparatus for correcting an optimal screen position of a digital TV. In the prior art, since a signal type of a broadcasting equipment used in a broadcasting station of an ATSC broadcasting region is slightly different, it is displayed on a horizontal and vertical scanning section when displaying it through a high-definition television. As the time difference occurs, underscan occurs on the left and right sides up and down of CALTI, and there is a problem in that the effective screen display cannot be made as much as possible to improve the overscan rate. Accordingly, the present invention has been made to solve the above-mentioned problems, and the horizontal and vertical scanning intervals generated due to the characteristics of the broadcasting equipment used by generating a periodic signal discrimination pulse by receiving a deflection retrace pulse and a luminance signal. By compensating for the error of C, it is effective to prevent the occurrence of the underscan and to provide an optimal screen without improving the overscan rate.

Description

Optimum screen position correction device of digital TV {APPARATUS FOR OPTIMUM ADJUSTING SCREEN POSITION OF DIGITAL TELEVISION}

The present invention relates to an apparatus for optimal screen position correction of digital TVs. In particular, the present invention relates to a high-definition TV receiving a high-definition TV system (ATSC) signal. The present invention relates to a digital TV optimal screen position correction device that compensates for errors in horizontal and vertical scanning sections to provide an optimal screen.

FIG. 1 is a block diagram illustrating a conventional digital TV. As shown in FIG. 1, an external high frequency signal is input to process a digital signal, thereby synchronizing a Hsync (Vsync) and an image signal (V) (U) (Y). A digital signal processing unit 10 for outputting a; Signal conversion and signal by receiving the vertical and horizontal deflection retrace pulses H _BLK (V _BLK ) and the image signals V, Y, U, and Hsync Vsync of the digital signal processor 10. An analog signal processor 20 for performing control and outputting an RG signal R (G) (B); A Citi unit 30 which receives an RG signal (R) (G) (B) of the analog signal processor 20 and displays it; A deflection for receiving the horizontal and vertical synchronization signals Hsync (Vsync) of the analog signal processor 20 and outputting the vertical and horizontal deflection retrace pulses H _BLK (V _BLK ) by a control signal I ² C. A controller 40; It is composed of a microcomputer 50 for outputting a control signal (I ² C) to the deflection control unit 40, the operation process according to the prior art configured as described above will be described in detail.

The digital signal processor 10 receiving an external high frequency signal processes the digital signal to output a synchronization signal Hsync (Vsync) and an image signal V (U) (Y), and the digital signal processor 10 The analog signal processing unit 20 that receives the horizontal and vertical synchronization signals Hsync and Vsync and the image signals V and U, which are processed by the B, deflects the horizontal and vertical synchronization signals Hsync and Vsync. Output to the control unit 40.

Here, the deflection control unit 40 receives the control signal I ² C of the microcomputer 50 and receives the horizontal and vertical synchronization signals Hsync (Vsync) input from the analog signal processing unit 20 and the deflection pulse. PEL-locked to output the horizontal and vertical deflection retrace pulse (H _BLK ) (V _BLK ) to the analog signal processor 20 again.

Accordingly, the analog signal processor 20 knows the input image signal V (U) (Y) during the horizontal and vertical scanning intervals by the horizontal and vertical deflection retrace pulses H _BLK (V _BLK ). The signal is converted into a signal (R) (G) (B) and outputted to the CIT unit 30 to display it.

At this time, the microcomputer 50 outputs the horizontal and vertical phase adjustment data set to a fixed value to the deflection control unit 40 so as to center the horizontal scan section and the vertical scan section, and receives the input deflection. The controller 40 centers the screen on the horizontal scanning section and the vertical scanning section by the set values.

Since the signal type of the broadcasting equipment used in the broadcasting station of the conventional ATSC broadcasting region is slightly different as described above, a time difference occurs in the horizontal and vertical scanning sections when displaying this through a high-definition television, and underscan occurs on the left and right sides of the CALTI. In order to solve this problem, an effective screen display cannot be achieved as much as the overscan rate is improved.

Accordingly, the present invention has been made to solve the above-mentioned problems, and the horizontal and vertical scanning intervals generated due to the characteristics of the broadcasting equipment used by generating a periodic signal discrimination pulse by receiving a deflection retrace pulse and a luminance signal. An object of the present invention is to provide an optimal screen position correction device for digital TV, which compensates an error of a digital TV to provide an optimal screen.

1 is a block diagram showing the configuration of a conventional digital TV.

Figure 2 is a block diagram showing the configuration of a digital TV to which the present invention is applied.

3 is a voltage waveform diagram of an input / output signal of a phase determination signal generator of FIG. 2.

*** Description of the symbols for the main parts of the drawings ***

100: digital signal processing unit 110: analog signal processing unit

120: Sipitibu 130: Deflection control unit

140: phase determination signal generator 150: microcomputer

The configuration of the present invention for achieving the above object is to receive a horizontal sync signal and a vertical sync signal to output a vertical, horizontal deflection retrace pulse by a control signal, the horizontal and vertical phase adjustment data to receive the horizontal A deflection control unit for adjusting the scan section and the vertical scan section; A phase determination signal generator for receiving a luminance signal and horizontal and vertical deflection retrace pulses of the deflection control unit and outputting horizontal and vertical periodic signal discrimination pulses; And a microcomputer configured to receive the horizontal and vertical periodic signal discrimination signals of the phase determination signal generator and output horizontal and vertical phase adjustment data so as to center the horizontal scan section and the vertical scan section.

The microcomputer receives a horizontal period signal discrimination pulse and counts the time of each low potential section, compares them alternately, and adjusts the horizontal phase adjustment data so that the time of each low potential section is the same. And to output the center of the horizontal scanning section.

In addition, the microcomputer receives a vertical period signal discrimination pulse and counts the time of each low potential section, compares them in turn, and adjusts the vertical phase adjustment data so that the time of each low potential section is the same. And to output the center of the vertical scanning section.

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

FIG. 2 is a block diagram showing a digital TV according to the present invention. As shown in FIG. 2, an external high frequency signal is input to process a digital signal, thereby synchronizing a digital signal (Hsync) (Vsync) and an image signal (V) (U). A digital signal processor 100 for outputting (Y); Signal conversion and signal by receiving the vertical and horizontal deflection retrace pulses H _BLK (V _BLK ) and the image signals V, U and Y of the digital signal processor 100 and Hsync Vsync. An analog signal processor (110) for performing control to output an RG signal (R) (G) (B); A Citi unit 120 for receiving and displaying an RG signal (R) (G) (B) of the analog signal processor 110; Receives the horizontal and vertical synchronization signal (Hsync) (Vsync) of the analog signal processing unit 110 and outputs the vertical, horizontal deflection retrace pulse (H _BLK ) (V _BLK ) by a control signal (I ² C), A deflection controller 130 which receives horizontal and vertical phase adjustment data and adjusts a horizontal scan section and a vertical scan section of the CT unit 120; In response to the luminance signal Y of the digital signal processing unit 100 and the horizontal and vertical deflection retrace pulses H _BLK (V _BLK ) of the deflection control unit 130, horizontal and vertical period signal discrimination pulses H _D ( A phase determination signal generator 140 outputting V _D ); The control signal I ² C is output to the deflection controller 130, and the horizontal and vertical periodic signal discrimination signals H _D (V _D ) of the phase determination signal generator 140 are input to each of the low signals. After counting the time in the potential section, it is composed of a microcomputer 150 that compares them alternately and adjusts and outputs the horizontal and vertical phase adjustment data so that the time in each low potential section is the same. It will be described in detail with reference to Figure 3 attached to the operation process according to the invention.

First, the digital signal processor 100 receiving an external high frequency signal processes the digital signal to output a synchronization signal Hsync (Vsync) and an image signal V (U) (Y), and the digital signal processor 100. ), The analog signal processing unit 110 receiving the horizontal and vertical synchronization signals Hsync (Vsync) and the image signals V, U, and Y processed by the horizontal and vertical synchronization signals Hsync (Vsync). Output to the deflection control unit 130.

Here, the deflection control unit 130 receives the control signal (I ² C) of the microcomputer 150 and locks the horizontal and vertical synchronization signals (Hsync) (Vsync) inputted by the deflection pulses and PEL. The retrace pulses H _BLK and V _BLK are output to the analog signal processor 110 and the phase determination signal generator 140 as shown in FIGS. 3A and _3D , respectively.

Accordingly, the analog signal processing unit 110 converts the input image signal V, U, and Y into an Algi ratio signal R, G, and B, and then the horizontal and vertical deflection retrace pulses. The HBLK outputs and displays the ALGB signals R and G during the horizontal and vertical scanning periods by H _BLK and V _BLK .

At this time, the phase determination signal generator 140 which receives the luminance signal Y of the digital signal processor 100 and the horizontal and vertical deflection retrace pulses H _BLK (V _BLK ) of the deflection control unit 130 is provided. By combining the luminance signal Y as shown in FIG. 3B and the horizontal deflection retrace pulse H _BLK as shown in FIG. 3A, a horizontal period signal discrimination pulse having a high potential during the horizontal return period and the horizontal signal period ( H _D ) is output to the microcomputer 150 as shown in FIG. 3C, and the luminance signal Y as shown in FIG. 3D and the vertical deflection retrace pulse as shown in FIG. 3E. (V _BLK ) is combined to output a vertical period signal discrimination pulse V _D having a high potential during the vertical retrace period and the vertical signal period to the microcomputer 150 as shown in FIG.

In the horizontal scanning section, the microcomputer 150 receives the horizontal periodic signal discrimination pulse H _D and receives the first, second, third, and fourth low potential sections Ta, Tb, and Tc. After counting the times of Td, they are alternately compared with each other so that the times of the first, second, third, and fourth low-potential sections Ta, Tb, Tc, and Td are the same. The horizontal phase adjustment data is adjusted and output.

For example, when the time of the low potential section Ta is greater than the low potential section Tb, the microcomputer 150 reduces the value of the horizontal phase adjustment data and outputs it to the deflection controller 130. The deflection control unit 130 adjusts the center of the screen by moving the horizontal scanning section forward to compensate for the underscan phenomenon occurring in front of the screen.

In addition, when the low potential section Ta is smaller than the next low potential section Tb, the microcomputer 150 increases the value of the horizontal phase adjustment data and outputs it to the deflection controller 130 so that it occurs behind the screen. In order to compensate for the under scan phenomenon, the horizontal scanning section is moved backward to center the screen.

In addition, even in the vertical scanning section, the microcomputer 150 counts the time of each of the low potential sections Ta ', Tb', Tc ', and Td' in the same manner as the horizontal scanning section. The vertical phase adjustment data are adjusted to be alternately compared with each other, and are output to the deflection controller 130 to adjust the vertical scanning interval to the center of the screen.

As described in detail above, the present invention generates a periodic signal discrimination pulse by receiving a deflection retrace pulse and a luminance signal, thereby compensating for errors in horizontal and vertical scanning intervals generated due to characteristics of broadcasting equipment, thereby overscan rate. It is effective to provide the optimal screen by preventing the occurrence of CALTI underscan without improvement.

Claims (3)

A deflection control unit for receiving a horizontal synchronizing signal and a vertical synchronizing signal and outputting vertical and horizontal deflection retrace pulses by a control signal, and receiving horizontal and vertical phase adjustment data to adjust horizontal scan sections and vertical scan sections of CALTI; A phase determination signal generator for receiving a luminance signal and horizontal and vertical deflection retrace pulses of the deflection control unit and outputting horizontal and vertical periodic signal discrimination pulses; And a microcomputer configured to receive the horizontal and vertical periodic signal discrimination signals of the phase determination signal generator and output horizontal and vertical phase adjustment data so as to center the horizontal and vertical scanning sections. Optimum screen position correction device. The method of claim 1, wherein the microcomputer receives a horizontal periodic signal discrimination pulse and counts the time of each low potential section, and then compares them alternately to adjust the horizontal phase so that the time of each low potential section is the same. A digital TV optimal screen position correction device, characterized in that the data is adjusted and output to adjust the center of the horizontal scanning section. The method of claim 1, wherein the microcomputer receives a vertical periodic signal discrimination pulse and counts the time of each low potential section, and compares them in turn to adjust the vertical phase so that the time of each low potential section is the same. A digital TV optimal screen position correction apparatus, characterized in that the data is adjusted and output to adjust the center of the vertical scanning section.