KR100281509B1 - How to Blend Digital On-Screen Displays - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a blending method for digital on-screen display, and more particularly to an OSD in an on-screen display (OSD) provided for various user interfaces, captions, etc., which are additionally supported on MPEG video images on a digital TV or PC The present invention relates to a blending processing method of mixing the original image data with a semi-transparent effect.

The conventional OSD blending processing method is not only inconvenient because the color lookup table (CLUT) needs to be reconfigured by adding 1 bit of blending flag data and reducing the amount of luminance signal data by this addition, but also reduces the amount of data affecting the actual display. You must take.

As shown in Fig. 3, the present invention divides the color lookup table (CLUT) into two independent areas, namely, an address area 30 corresponding to the base area of the OSD and an address area 31 not corresponding to the OSD. The digital on-screen display blending process can be performed by giving a blending ratio corresponding to two address areas, respectively.

Description

How to Blend Digital On-Screen Displays

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a blending method for digital on-screen display, and more particularly to an OSD in an on-screen display (OSD) provided for various user interfaces, captions, etc., which are additionally supported on MPEG video images on a digital TV or PC The present invention relates to a blending processing method of mixing the original image data with a semi-transparent effect.

A circuit configuration for processing an OSD on an MPEG video image on a digital TV or a PC is shown in FIG.

As shown in Fig. 1, the control processor CMD is received from the host processor 1, and the image processing unit 2 reads OSD information of the memory unit 3, and this OSD information causes the TV encoder 4 to operate. Through converting into an analog TV signal through the OSD on the display unit (5).

The image processor 2 selectively controls switching of the video information of the moving image image processing unit 201 and the OSD processing unit 202 by interpreting the control command CMD, and at this time, the moving image memory area 301 of the memory unit 3 or the like. The process of appropriately reading or writing the information in the OSD memory area 302 is performed in parallel.

As described above, the raw image information and the OSD information processed by the image processing unit 2 convert the Y, Cb, Cr signals into R, G, and B signals through the encoder 4 and display them on the display unit 5.

In the display unit 5, 501 is an original video image, 502 is an OSD image, and the display unit 5 is an external output device such as a TV or a monitor.

As described above, when OSD processing is performed on an MPEG video image on a digital TV or a PC, a color lookup table (CLUT) is referred to for color processing of OSD information.

The OSD bitmap 302 stored in the external memory consists of 2 bits, 4 bits, or 16 bits per pixel.

The color lookup table (CLUT) supports 256 colors when 8 bits are used per pixel, and this 8-bit data in the OSD memory (bitmap) is used as an index for addressing the color lookup table (CLUT). By doing so, the corresponding color data of the color lookup table (CLUT) corresponding to the data (address: Addr) is read.

In order to implement special effects such as color background of the color look-up table (CLUT) and semi-transparent effect on OSD background and OSD information in the OSD processing, blending of the original image data and OSD data at an appropriate ratio is blended. Processing.

The information necessary for this blending process includes blending data indicating the ratio of the original image data and the OSD data.

If the 16-step blending effect is to be achieved, at least 4 bits of blending data are required.

Conventionally, the blending data may be added for each color information (Y, Cb, Cr) of the color lookup table for the OSD blending process. In this case, however, the memory size is increased. Similarly, one-bit blending flag data 21 for determining whether to blend is added to the color data designated by each address of the color lookup table (CLUT) 20.

If the added blending flag data 20 is set to '1', it means blending, giving the blending ratio with 4 bits of data in the OSD header. If it is '0', it is unconditionally transparent or completely opaque. OSD output signal is made.

When 1-bit data is added in this way, the 16-bit system including the 8-bit luminance signal (Y) and 4 bits of the color signal (Cb, Cr) is changed to the 17-bit system. Therefore, a 16-bit wide color lookup table (CLUT) is used to facilitate hardware configuration. 1 bit of luminance signal is reduced to use color lookup table (CLUT) reconstructed with total 16 bit system of 7 bits of luminance signal, 4 bits of color signal and 1 additional blending flag data 21. do.

As described above, the conventional OSD blending processing method requires reconstruction of the color lookup table (CLUT) by adding 1 bit of blending flag data and reducing the amount of luminance signal data by the added amount, thereby reducing the amount of data affecting the actual display. You have to take the disadvantages.

The present invention divides the color lookup table (CLUT) into two independent regions, one for which the blending process is to be performed and the other for which the blending process is not performed, and provides a blending ratio for each region in the OSD header. It was possible to perform.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows a circuit configuration for processing an OSD on an MPEG video image on a digital TV or PC.

2 illustrates a conventional OSD blending method.

3 illustrates the OSD blending method of the present invention.

4 is a view showing an OSD header structure according to the present invention.

The digital on-screen display blending method of the present invention first has two blending values for each region, where one value means a blending value at a specific color value.

Blending values in the other remaining colors use the other value.

Here, the blending of a specific value can be applied to the background of the OSD area. For example, the background should have a relatively transparent or translucent effect unlike other OSD areas. Need a value.

In addition, by adding this value to the information of each region, two different blending values can be obtained for each region without restriction of color expression.

The digital on-screen display blending method of the present invention will be described with reference to FIG.

3 shows a color lookup table (CLUT) for the case of 8-bit 256 color resources per pixel.

Among the addresses Addr on the color lookup table CLUT, the '0' address 30 is allocated as the color data area (Background) for blending, and the 1-255 address 31 is allocated as the remaining color data area (Foreground). One case is shown as an example.

In the present invention, the location (address) of the color lookup table CLUT is divided into two areas 30 and 31, and a blending ratio is given by 4 bits for each area from the OSD local header.

That is, as shown in Fig. 4, the OSD command area 41 is divided into one part 41a in the OSD area divided into areas such as command 41, color lookup table (CLUT) 42, bitmap 43, and the like. The blending ratio to be applied to the color signal of the address '0' of the color lookup table CLUT is stored, and the blending ratio to be commonly applied to the signals of the remaining color lookup table CLUT addresses is stored in the other part 41b.

Then, when the value of the OSD bitmap is '0', the color signal at address '0' of the color lookup table (CLUT) is read and the blending ratio of the color signal (color data) will be determined by the value given to the area 41a. When the value of the OSD bitmap is any other value (1 to 255), the color signal of the address of the corresponding color lookup table (CLUT) is obtained as the OSD signal, and the blending ratio of the color signals is given to the command area 41b. It is decided.

Therefore, in response to the command CMD from the host 1, the image processing unit 2 performs OSD processing with reference to the OSD data of the memory unit 3. In the case of using 8 bits of color per pixel for the OSD data displayed in, one address (Addr'0 ') on the color lookup table (CLUT) will be the color data 30 for blending the background image. The remaining addresses Addr'1-255 'will be color data 31 loaded on the OSD.

This address '0', designated as the background color signal, may be specified differently depending on the implementation.

For example, if the background color is address' 0 'and the remaining colors are' 1 to 255 'differently,' 0 to 15 'can be designated as the background color and '16 to 255' can be assigned as the rest. In the method of dividing by, each region may be allocated differently according to an implementation example.

That is, in the present invention, the position (address) of the color lookup table (CLUT) is viewed and divided into two independent regions to perform the blending process, and the blending address and the blending ratio are given by the OSD local header for each region of the multiple OSD. The blending process of the desired bar can be used freely.

According to the digital on-screen display blending method of the present invention, the blending process is performed by looking at the position (address) of the color look-up table (CLUT) into two independent regions, and reducing the blending ratio for each region in the OSD local header. Can be.

Therefore, compared to the case of adding one bit of blending flag data in the related art, using the color lookup table (CLUT) without reconstruction of the data of the color lookup table (CLUT), the different blending values are free for each OSD region without restriction of color expression. I can have it.

Claims (3)

In order to perform the digital on-screen display (OSD), the blending process is performed by mixing the original image data and the OSD data, and the color look-up table (CLUT) to be accessed for the blending process is divided into a plurality of independent areas to separate the divided areas. A digital on-screen display blending method characterized in that a blending process is performed for a specific color value in the OSD header as a blending color value. The method of claim 1, wherein in displaying a plurality of OSDs simultaneously on one screen, an address of a color lookup table (CLUT) for accessing the blending color value in an OSD local header for each OSD area is designated. A method for blending a digital on-screen display, characterized in that each OSD region can have a different blending value. The method of claim 1 or 2, wherein a specific address of a color lookup table (CLUT) is designated as an area for blending in the OSD header, and a blending ratio for the area is given together in the OSD header. Digital on-screen display blending method.