KR0178182B1 - Automation screen ratio transformation circuit - Google Patents

Abstract

The present invention relates to a TV automatic aspect ratio conversion circuit adapted to adaptively convert to an aspect ratio of a cinema mode for image software having different aspect ratios input to a TV having a 16: 9 aspect ratio. A clamping circuit section, a clock signal generator, and an analog-digital converter (10, 12, 14) for digitally converting a video signal corresponding to a predetermined check line of the video software on the basis of a clock signal of A vertical reset circuit unit for generating a data conversion signal for a check line (vertical scan line), a horizontal synchronous signal counter and a screen check signal generation unit 16, 18, and 20 for detecting the image area and the blanking area based on the predetermined area; Binary-hexadecimal data conversion for aspect ratio detection of the digitally converted luminance data corresponding to the check line based on a clock signal of A data conversion unit 22 which performs processing, an aspect ratio detection unit 24 which determines a blanking area and an image signal area of the image soft based on the hexadecimal data converted luminance data, and based on the detected screen display area. And an aspect ratio change setting section 26 for setting the aspect ratio change to the aspect ratio, and a control unit 28 for controlling the aspect ratio change of the image soft according to the setting of the aspect ratio change. It is a useful invention that determines the state of the blanking area and automatically converts an image having an appropriate aspect ratio to be displayed as the cinema mode according to the input of the image soft.

Description

TV's automatic aspect ratio conversion circuit

1 is a block diagram showing the configuration of the automatic aspect ratio conversion circuit of the TV according to a preferred embodiment of the present invention.

2 is a view for explaining an aspect ratio conversion operation performed by the automatic aspect ratio conversion circuit of the TV according to the present invention shown in FIG.

3 is a waveform diagram illustrating the operation of the automatic aspect ratio conversion circuit of the TV according to the present invention shown in FIG.

* Explanation of symbols for main parts of the drawings

10: clamping circuit section 12: clock signal generation section

14 Analog-to-Digital Converter 16 Vertical Reset Circuit

18: horizontal synchronous signal counter 20: screen check signal generation unit

22: data conversion unit 24: aspect ratio detection unit

26: aspect ratio change setting unit 28: control unit

The present invention relates to a TV, and more particularly, to an automatic aspect ratio conversion circuit of a TV adapted to adaptively convert to an aspect ratio of a cinema mode for video software having different aspect ratios inputted to a TV having a 16: 9 aspect ratio. .

As is well known, TVs that reproduce video signals and audio signals of broadcast programs transmitted through a wired or wireless channel from a broadcasting station are developed as TVs for expressing images of 4: 9 aspect ratio from 4: 3 aspect ratio. In such a TV, when a viewer selects an appropriate aspect ratio according to a broadcast program having a 16: 9 aspect ratio and a 4: 3 aspect ratio, the screen is adjusted in the vertical direction while controlling the syringe in the horizontal direction under the control of a control means such as a microcomputer. Increasing / reducing allows switching between 4: 3 and 16: 9 aspect ratios.

However, when the aspect ratio change display is performed in the cinema mode based on different types of image software input to the TV, the viewer adaptively adapts the type of the image software to the type of the image software. This is accompanied by the inconvenience of having to select and execute a mode, and also has the disadvantage that multiple key operations are required in order to match the correct aspect ratio for different video software.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described state of the art, and an object thereof is to provide an automatic aspect ratio conversion circuit for a TV which is adapted to automatically convert screen images by a cinema mode to image software having different aspect ratios. .

In order to achieve the above object, according to a preferred embodiment of the present invention, in a TV that can be changed to the aspect ratio based on the aspect ratio of the image soft input to different types, the specified check line (vertical scanning line) of the image soft A clamp circuit for clamping the luminance signal separated from the video signal corresponding to the clock signal generator, a clock signal generator for generating the predetermined clock signal in phase synchronization with a horizontal synchronous signal separated from the video signal, and a clock signal generation A data converting means, which is controlled by a clock signal generated by the unit, and comprises an analog-digital converting unit for digitally converting the luminance signal of the clamped check line; A vertical reset circuit section for generating a vertical reset signal based on a vertical synchronization signal of the video signal with respect to a check line specified sequentially when the aspect ratio change mode is set, and being reset by the vertical reset signal to be horizontal to the check line A horizontal synchronous signal counter for counting a synchronous signal, and a screen check signal generation unit for generating a screen check signal for determining a level of a luminance signal corresponding to the vertical synchronous line based on a count result of the horizontal synchronous signal counter Screen area detection signal generation means configured to include; Data processing means comprising a binary hexadecimal converter for performing data conversion processing on the digitally converted luminance signal data corresponding to the check line based on the screen check signal to hexadecimal data for level detection; Aspect ratio detection means for detecting the blanking area and the image signal area of the image software based on the hexadecimal data subjected to data conversion processing for the level detection, and the aspect ratio change setting for setting the aspect ratio change based on the detected screen display area. Means, an automatic aspect ratio converting circuit of a television is provided which includes control means for controlling the aspect ratio change of the image soft according to the setting of the aspect ratio change.

Preferably, the aspect ratio detecting means compares at least eight fields of luminance data for the specified check line to perform aspect ratio detection.

The aspect ratio change setting means outputs a signal to cause the aspect ratio change (cinema image) to be performed for the extension processing of the image region based on the aspect ratio determined by the aspect ratio detection means.

The control means controls the program or the vertical deflection means when setting the aspect ratio change so that the aspect ratio of the image soft is extended.

According to the automatic aspect ratio conversion circuit of the TV according to the present invention configured as described above, the blanking area and the image area of the screen are detected while changing the check line for the determination of the aspect ratio for the image software having different aspect ratios under the control of the control means. The aspect ratio is determined, and change display of the cinema image is performed adaptively to the aspect ratio of the determined image software.

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

1 is a block diagram showing an automatic aspect ratio conversion circuit of a TV according to a preferred embodiment of the present invention, and reference numerals 10, 12, and 14 denote check lines (i.e. A clamp circuit portion, a clock signal generation portion, and an analog-digital conversion portion, which constitute data conversion means for digitizing the luminance signal corresponding to the vertical scan line to enable level determination, the clamp circuit portion indicated by 10 is an image processing means (not shown). Clamps the level for digitally converting the luminance signal Y (the luminance signal of the designated check line) separated from the image signal of the input image software by the reference signal, and the clock signal generation unit indicated by 12 is a horizontal synchronous signal of the image signal. It is equipped with PLL (Phase Locked Loop) function to obtain clock signal that is synchronized to Hsync to generate clock signals (CLK1, CLK2). The analog-to-digital conversion unit 14 denoted by the clock signal CLK1 generated by the clock signal generation unit 12 is clocked and the luminance signal of the check line clamped by the clamp circuit unit 10. In order to level determine (Y), digital conversion is performed to data of a predetermined bit (8 bits in the present invention).

Further, 16, 18 and 20 are means for generating a setting signal (under the control of the control means described later) of the check line to detect the blanking area of the screen and the video area for detecting the screen area of the video signal in the present invention. The vertical reset circuit part, the horizontal synchronous signal counter and the screen check signal generation part are shown. The vertical reset circuit part 16 generates the vertical reset signal based on the control of the control means described later when setting the aspect ratio change mode. The horizontal synchronous signal counter 18 is reset by the vertical reset signal to count the horizontal synchronous signal Hsync of the video signal with respect to the check line, and the screen check signal generator 20) shows the blanking area and zero of the screen based on the counting result of the horizontal synchronization signal by the horizontal synchronization signal counter 18 under the control of the control means described later. Corresponding to the check line designated for checking the phase region, a signal (ie, a screen check signal) for controlling the digital conversion in the analog-digital conversion unit 14 is generated.

Further, reference numeral 22 denotes a data conversion unit as data processing means for converting and processing digital data corresponding to the check line into data for level determination based on the screen check signal generated by the screen check signal generation unit 20 in the present invention. As shown, the data converter 22 synchronizes the luminance signal data obtained by the digital conversion (binary data) based on the screen check signal to the clock signal CLK2 generated by the clock signal generator 12. Convert to hexadecimal data.

24 denotes an aspect ratio detecting unit serving as a means for detecting an aspect ratio by determining whether the check line is a blanking region or an image region based on the image data converted into hexadecimal data, and the aspect ratio detecting unit 24 checks the check. When the hexadecimal conversion data for a line is below a predetermined value (e.g., OA) (no synchronization signal), a signal (e.g., high level) that determines that the check line is included in the blanking area (or black area). On the other hand, if the hexadecimal conversion data is equal to or greater than a predetermined value (i.e., OA) (synchronized signal is present), a signal (e.g., low level) of a level indicating a state where the check line is included in the image area do.

26 denotes an aspect ratio change setting unit as a means for setting the aspect ratio change of the image software on the basis of the screen area detected by the aspect ratio detection unit 24. The aspect ratio change setting unit 26 denotes the screen unit detection unit ( 24) when the aspect ratio of the image soft (e.g. 4: 3) is detected, i.e., when the determination of the blanking areas included in the image software of different aspect ratios is made, the image area is vertically stretched with respect to the blanking area. The aspect ratio change setting signal is provided so that the image display by the cinema mode is performed. The aspect ratio change setting section 26 sequentially assigns a check line to the image software under the aspect ratio change mode, and when the check line is detected as a blanking area, a signal of a level (for example, to set the screen display mode to the cinema mode) On the other hand, when the determination signal of the screen display area is, for example, a low level, the level of setting the screen display mode to the normal screen display mode (image display in 16: 9 or 4: 3 aspect ratio) is provided. Provide a signal (eg, low level).

And 28 denotes a control unit as a means for performing control for automatically changing the aspect ratio of the image reproduced by the image software on the basis of the aspect ratio change setting signal when the aspect ratio change mode is designated. ) Controls the stretching process in the vertical direction when the aspect ratio change setting signal indicates a cinema mode (i.e., high level), while the aspect ratio change setting signal indicates an image display of 16: 9 or 4: 3 aspect ratio. The screen display corresponding to the display mode is controlled.

Next, the operation of the automatic aspect ratio conversion circuit of the TV according to the present invention configured as described above will be described in detail with reference to FIGS. 2 and 3.

First, when a command for designating an aspect ratio conversion mode is externally input to the controller 28, the controller 28 is configured to display a screen formed by different types of image software with respect to the screen check signal generation unit 20. To check the blanking area and the image area (refer to FIG. 2 (a) or (b)), check lines are sequentially assigned on the screen to control to generate a screen check signal for checking the aspect ratio of the image software. The vertical reset circuit unit 16 generates a vertical reset signal at the falling edge of the vertical synchronization signal Vsync (see FIG. 3 (a)) of the designated check line and resets the horizontal synchronization signal counter 18. Will perform the set. The horizontal synchronous signal counter 18 then counts the horizontal synchronous signal Hsync (see FIG. 3 (b)) corresponding to the designated check line and applies the count result to the screen check signal generation unit 20. do.

The screen check signal generation unit 20 generates a signal for digitizing the luminance signal and provides it as the digital enable signal to determine the level of the luminance signal corresponding to the check line designated by the controller 28. Done.

Accordingly, the luminance signal Y of the corresponding check line clamped to the level for digital conversion in the clamping circuit unit 10 is digitalized by the analog-digital conversion unit 14 to the binary-hexadecimal converter. The data corresponding to the check line is applied to the data conversion section 22, which is activated by the enable signal and digitally converted by the analog-to-digital conversion section 14. Convert to binary data.

When the hexadecimal data is applied to the aspect ratio detection unit 24, the aspect ratio detection unit 24 determines the blanking (or black) area and the image area of the image displayed on one screen based on the hexadecimal data (Fig. 3). (c) and (d). If the hexadecimal data corresponding to the check line is less than or equal to a predetermined value (e.g., OA), the check line includes a blanking area in which display of a video signal is not performed. Or a black level) and outputs a high level signal, for example, and if the hexadecimal data is greater than a predetermined value (ie, OA), the check line displays a normal video signal in which a synchronization signal exists. For example, a low level signal is determined to determine a state included in the image area. Therefore, even when the types of the input image software are different in the form illustrated in FIGS. 2A and 2B, check lines (ie, horizontal scan lines) are sequentially designated while the check lines are placed on the blanking memory. It is possible to determine whether or not the image is included in the image area or determine the aspect ratio of the image software (see FIGS. 3C and 3D). Further, the area determination for the check line is, for example, when a black background included in the video signal of the image soft is included in the black background, the black background screen is determined as a blanking screen. At least eight fields are determined for the same check line in order to prevent an error that is caused, so that the aspect ratio can be switched when the determination result is the same.

When the level (high level or low level) of such an aspect ratio detection signal is applied to the aspect ratio change setting section 26, the aspect ratio change setting section 26 receives a high level signal indicating detection of the blanking area. While outputting a high level signal for changing the current display mode to a cinema mode, for example, when a low level signal indicating the detection of the image area is input, the current display mode is changed to 16: 9 or 4: 3 aspect ratio. For example, a low level signal for specifying the display mode is output.

Then, when the high-level signal for designating the change to the cinema mode is input from the aspect ratio change setting unit 26, the controller 30 outputs a control signal for performing vertical extension processing, for example, by a program procedure. (Not shown) or control signals for deflection control for the deflection processing means (not shown) to control screen display with the blanking area removed. Therefore, even when different types of image software are input in the form illustrated in FIG. 2 (a) or (b), the aspect ratio of the image software (a ratio between the blanking area and the image area) is detected and the difference between the blanking areas is obtained. It is possible to adapt automatically to the aspect ratio of the cinema mode.

As described above, according to the TV's automatic aspect ratio converting circuit according to the present invention, the blanking area included in the image signal of the input image software is judged, and the aspect ratio is automatically changed to display an image having an appropriate aspect ratio. It is possible to eliminate repetitive multiple key operations.

Claims (1)

In the TV which can be changed to the aspect ratio based on the aspect ratio of the image software inputted in different types, the clamp circuit unit for clamping the luminance signal separated from the image signal corresponding to the designated check line (vertical scanning line) of the image software ( 10) and a clock signal generation unit 12 for generating the predetermined clock signal in phase synchronization with a horizontal synchronization signal separated from the video signal, and a clock signal generated by the clock signal generation unit 12. Data conversion means configured to include an analog-digital conversion unit (14) controlled by the digital signal to convert the luminance signal of the clamped check line; A vertical reset circuit section 16 for generating a vertical reset signal based on a vertical synchronization signal of the video signal with respect to a check line designated sequentially when the aspect ratio change mode is set, and reset by the vertical reset signal; A screen check signal for determining a level of a luminance signal corresponding to the vertical synchronization line based on a horizontal synchronization signal counter 18 for counting a horizontal synchronization signal with respect to the horizontal synchronization signal counter 18 and a count result by the horizontal synchronization signal counter 18 A screen area detection signal generation means including a screen check signal generation unit 20 for generating a signal; Data processing means (22) comprising a binary hexadecimal converter for performing data conversion processing of the digitally converted luminance signal data corresponding to the check line to hexadecimal data for level detection based on the screen check signal; Aspect ratio detection means (24) for detecting a blanking area and an image signal area of said image software based on the hexadecimal data subjected to data conversion processing for said level detection; Aspect ratio change setting means (26) for setting an aspect ratio change based on the detected screen display area; And control means (28) for controlling the aspect ratio change of the image software according to the setting of the aspect ratio change.