JPH07192129A - Filtration system of input video image data - Google Patents

Abstract

PURPOSE: To reduce alias distortion generated at the time of operating an image, especially, at the time of dividing the video into several small zones. CONSTITUTION: An input image is constituted of plural tiles including plural pixels. For each tile in a first type in which all the pixels belonging to the tile are present in the same small area, the local compressibility of the tile by an operation is calculated, and for each tile in which the pixels belonging to the tile are present in more than two small areas, the local compressibility of the adjacent tile in the first type closest to each pixel of each tile in the same small zones as each pixel is selected. Then, the pixels of the plural tiles are spatially filtered under the consideration of the local compressibility.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an exhaustive alias filter control method (method and apparatus) for split images, and more particularly, for producing an image containing an input video image divided into several partial images. The present invention relates to a method for eliminating alias filtering of input video image data to be mapped to the.

[0002]

BACKGROUND OF THE INVENTION Video footage is often manipulated to achieve special effects. One example is shown in FIG. However, when the image is manipulated in this way, aliasing of the image occurs due to compression of the image. At present, it is considered necessary to divide the input image into a certain number of partial images 20 as shown in FIG. 2 when operating the image.

[0003]

SUMMARY OF THE INVENTION It is an object of the present invention to obtain a scheme for reducing alias distortions that occur when manipulating a video, especially when trying to divide the video into several sub-pictures (or subregions). Is.

[0004]

According to the present invention, when the input video image data is operated to generate the output video image data representing the output video image, a small area of the input video image is used for the operation. Input video image if the output video image includes at least one of the sub-regions and the input image is treated as consisting of multiple tiles, each tile including multiple pixels. A method is provided for filtering input video image data representing The method is such that, when a tile when all the pixels having a predetermined spatial relationship with the tile are in the same sub-area, the tile is of the first type, and the tile of the first type is A step of calculating a local compression ratio representing a degree of compression of the tile by comparing an interval before operation of a pixel having a predetermined spatial relationship with the tile with an interval after operation; For each tile whose pixels are in two or more sub-regions, for each individual pixel of each of these tiles, within the same sub-region closest to each individual pixel and each individual pixel Selecting the local compression ratio of the first type of neighboring tiles, and spatially filtering the pixels of the plurality of tiles taking into account the local compression ratio. No.

The invention also provides that when manipulating the input video image data to produce output video image data representative of the output video image, the operation includes dividing the input video image into subregions, and An apparatus is also provided for filtering input video image data representative of the input video image when the image includes at least one of the sub-regions and the input image is treated as comprising a plurality of tiles, each tile comprising a plurality of pixels. To do. The apparatus defines a tile of the first type when all the pixels having a predetermined spatial relationship with the tile are in the same sub-region, and for each tile of the first type, the tile A calculation unit that calculates a local compression ratio indicating the degree to which a tile is compressed by comparing an interval before operation of a pixel having a predetermined spatial relationship with the tile with an interval after operation, and each tile and a predetermined value. For each individual pixel of each tile where the pixels of the relationship are in two or more sub-areas, the neighborhood of the first type closest to the individual pixel and in the same sub-area as the individual pixel. It comprises selection means for selecting a local compression ratio of tiles, and filtering means for spatially filtering the pixels of said plurality of tiles taking into account said local compression ratio.

Exhaust alias filtering can occur due to local compression ratios calculated in the horizontal and vertical directions based on the horizontal and vertical compression introduced in the image manipulation. That is, the image is divided in the horizontal and vertical directions to form a plurality of tiles, the local compression ratio in the horizontal and vertical directions is determined, and the elimination alias filter is operated so as to operate at the “tile level” for the entire image. Control it.

If the input image is divided and nothing is done, the image will be irregular as a result of the alias filtering, but the present invention provides a method for properly filtering the input image even if such division is performed. To do.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be specifically described below with reference to the drawings. FIG. 1 is a diagram showing an example of a known video operation. FIG. 2 shows a variation of the operation of FIG. 1 that splits the video into four partial videos 20.

By using the video image processing device, the size of the input image which normally occupies the entire screen can be changed,
And / or it is known to treat the screen so that it appears to be on a three-dimensional surface. An example of this type of processing is shown in FIG. 1, in which an image is projected onto a perspective surface extending toward the inside of the screen. In implementation, this is done in the writer system or the reader system. That is, the video operation is performed by writing the pixel data to an address different from the original information address or reading the pixel data from a special address different from the original information address.

When the image data is processed in this way, the image is compressed and alias distortion appears in the image. In order to solve this problem, we would like to propose a video processing device that uses an anti-aliasing filter that properly filters the video data before the operation so that the alias distortion is reduced during the operation.

The image is first, at least conceptually, divided into a plurality of "tiles" 10 as shown in FIG. And
The width and height of each tile are examined before and after the operation to individually determine the horizontal and vertical compression ratios for each tile and set the appropriate bandwidth for the horizontal and vertical prefilters.

FIG. 6 shows an example of a concrete 4 × 4 (16) pixel tile 10. In this example, the horizontal and vertical compression rates of tile 10 are set to pixels A and A before and after the operation, respectively.
_H, is calculated by comparing the distance between the pixels A and A _V. Considering the horizontal compression ratio in detail, the spacing between pixels A and A _H before the operation is obviously the standard 4 pixel spacing. However, after the operation, when tile 10 is compressed to half width as shown in FIG. 7, the spacing between pixels A and A _H is reduced to only 2 pixels. Such compression is considered to occur only in the horizontal direction or only in the vertical direction, but in FIG.
Shows a case reduced to only two pixels even spacing of the pixels A and A _V.

Considering in more detail the calculation of the local compression ratio based on the parameters shown in FIG. 11, the equations for the horizontal and vertical local compression ratios are derived as follows.

[0014]

[Equation 1]

The values of xh and xv are obtained by calculating the difference between the horizontal tile addresses of horizontally and vertically adjacent corners, respectively. The yh and yv values are similarly calculated from the vertical tile addresses.

The values of xh and yh are processed by a Cartesian polar coordinate converter to generate their magnitude and angle α. The magnitudes of xv and yv and the angle β are similarly generated.

The value of sin (β-α) is obtained from a look-up table (LUT) stored in the PROM.

After calculating LSX and LSY, the final filter control data is derived as follows. If LSF (local compression ratio) = 1, then the data value is limited to 0 × 1F (a pre-filter bypass coefficient set is chosen, since under this situation no alias rejection filtering is required). L
If SF <1, the data value is quantized to 5 bits in the range 0x00 (minimum filter bandwidth) to 0x1E (maximum filter bandwidth). These data values will select one of the 31 possible low pass filter coefficient sets of the prefilter.

Therefore, the H (horizontal) and V (vertical) filters are separately controlled and applied to all pixels in the tile for which the LSF has been calculated.

As shown in FIG. 2, when an image is placed on a three-dimensional surface, the input image can be divided into a certain number of partial images (segments) 20.

In the most flexible system, the video is
It can be divided by the desired pixel. But as mentioned above
According to this device, an image is displayed as a pixel C as shown in FIG.
Dividing along the vertical line passing between D, tile 10
When calculating the local compression ratio, the pixel data in tile 10
Pixels A and A _H
Will increase to 7 pixels wide. Therefore, this
If the above method for calculating the proper compression ratio
Is a comparison of pixel addresses that span both sides of the divider.
It is no longer suitable because it does not show exact compression.

As a matter of fact, the above method does not prevent the tiles from being tiled, even if the partitioning is along the boundaries of the tiles, and yet the partitioning may separate the pixel addresses used to calculate the local compression ratio. Not suitable for equipment.

Therefore, when it seems that the local compression rate of a specific tile cannot be calculated as it is, that is, when a plurality of pixels used for calculating the compression rate of a certain tile are divided into two or more partial images. We propose a method that takes the local compression ratios of adjacent tiles that have no influence as the local compression ratios of pixels of the tile.

It is necessary to determine which local compression ratio should be used for the tiles at the boundaries of the partition. Figure 3
The division boundary 30 generated in the tile 10 is shown. 4
0 indicates a tile boundary. This decision is further complicated when demultiplexing the manipulated data, especially because of the higher processing rates used for high definition video footage for HDTV.

The proposed strategy is to know the previous data before the particular tile being processed and, as the compression ratio of the pixels of the tiles being divided, on the same side with respect to the dividing boundaries, eg in the same output sub-image, It is to take the compression ratio of the nearest complete or undivided tile.

Since the split boundary can occur at any pixel, ie any phase of the video data, the incoming local compression ratio is such that the perfect tile closest to filtering the data near the split boundary. In order to decide which of these should be selected, it must be possible to resolve to pixel or phase accuracy.

In FIG. 4, the shaded areas are divided boundaries 30.
We present the current tile that surrounds, and show the proposed solution above when we need to derive the local compression ratio from the closest complete tile. The following equation describes the proposed solution (see Figure 5). When X _IN <X _S , select the value of the tile before the current tile. When X _IN > X _S , select the value of the tile after the current tile. When Y _IN <Y _S , select the tile before the current tile. When Y _IN > Y _S , the value of the tile after the current tile is selected, where X _IN and Y _IN indicate the horizontal and vertical addresses of the image to be operated, and X _S and Y _S are horizontal and vertical. Indicates a vertical split axis.

FIG. 5 is a more detailed view of the tile area to be selected for local compression ratios when the current tile area surrounds a split boundary. Four arrows (numbered from 1 to 4) indicate from which tile of a proper partial image (divided image) the local compression ratio of the shaded tile surrounding the division boundary is taken.

9 and 10 show at the pixel level
FIG. 6 is also an arrow showing which neighboring tiles are chosen to determine the local compression ratio for the pixels affected by the division.

Since the above division can occur in any pixel or line, the method can be applied not only to video data that has not been serial-parallel converted, but also to data that has been serial-parallel converted. It may be required to provide different local compression ratios for each phase of.

[0031]

As described above, according to the present invention,
It is possible to reduce aliasing distortions that occur when manipulating an image, especially when trying to divide the image into several sub-regions.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of a known video operation.

FIG. 2 is a diagram showing a modification of the video operation of FIG. 1 in which the video is divided into four partial videos.

FIG. 3 is an enlarged view showing an example of a division boundary occurring in a tile of an image.

FIG. 4 is a diagram showing an example in which a tile is currently on a division boundary.

FIG. 5 is a diagram showing a method of selecting a tile other than the current tile in the case of FIG.

FIG. 6 is a diagram showing an example of tiles before compression at the pixel level.

FIG. 7 is a diagram showing an example of a tile after compression at a pixel level.

FIG. 8 is a diagram showing problems at the time of dividing an image at a pixel level.

9 shows a first example at the pixel level according to the method of FIG.

10 shows a second example at the pixel level according to the method of FIG.

FIG. 11 is a diagram showing a pixel relationship for calculating a local compression ratio.

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Office reference number FI technical display location H04N 5/262

Claims (16)

[Claims] 1. When operating input video image data to create output video image data representing an output video image,
The operation involves splitting the input video footage into subregions,
And a method of filtering input video image data representative of the input video image when the output video image includes at least one of the sub-areas and treats the input image as consisting of tiles each pixel comprising a plurality of pixels. When all the pixels having a predetermined spatial relationship with the tile are in the same small area as the first type, the operation is performed for each tile of the first type. Calculating a local compression ratio representing the degree to which the tile is compressed by comparing the pre-operation spacing of pixels in the predetermined spatial relationship with the tile with the post-operation spacing; For each tile in which the pixels having the above-mentioned predetermined relationship are divided into two or more of the sub-regions, for each pixel of each of these tiles, Selecting a local compression ratio of said first type of neighboring tiles within said sub-area closest to the xcel and in the same sub-area as each individual pixel, said pixels of said plurality of tiles being spatial A method of filtering input video image data, the method comprising: 2. The method of claim 1, wherein the input video image is treated as horizontally and vertically divided to form rectangular and / or square tiles. 3. The method of claim 2, wherein at least one of the pixels in the predetermined spatial relationship with a tile is at a corner of the tile. 4. The method of claim 2 or 3, wherein at least one of the pixels in the predetermined spatial relationship with a tile is at a corner of a neighboring tile. 5. The calculating step comprises comparing a pre-operation address of a pixel in the predetermined spatial relationship with a tile with a post-operation interval to determine horizontal and vertical compression of the tile by the operation. 5. The method of claim 2, 3 or 4 including. 6. Filtering each pixel in each tile by taking into account the vertical local compression of the neighboring tiles of the first type that are closest to the pixel and within the same sub-area. The method according to any one of 5 to 5. 7. Filtering each pixel in each tile by taking into account the horizontal local compressibility of the neighboring tiles of the first type that are closest to the pixel and within the same sub-area. Item 6. The method according to any one of items 6 to 6. 8. The method according to claim 1, wherein each tile comprises 16 pixels arranged in 4 rows and 4 columns. 9. When manipulating the input video image data to create output video image data representing the output video image,
The operation involves splitting the input video footage into subregions,
And an apparatus for filtering input video image data representative of the input video image when the output video image includes at least one of the sub-areas and treats the input image as consisting of tiles each pixel comprising a plurality of pixels. When all the pixels having a predetermined spatial relationship with the tile are in the same small area as the first type, the operation is performed for each tile of the first type. Means for calculating a local compression ratio indicating the degree to which the tile is compressed by comparing the interval before the operation of the pixels having the predetermined spatial relationship with the tile with the interval after the operation; For each individual pixel of each tile when the pixel having the above-mentioned predetermined relationship with each other is within the two or more sub-areas, Means for selecting a local compression ratio of the neighboring tiles of the first type within the same sub-area as individual pixels; and means for spatially filtering the pixels of the plurality of tiles taking the local compression ratio into consideration. An input video image data filtering device comprising. 10. The apparatus of claim 9, wherein the input video image is treated as horizontally and vertically divided to form rectangular and / or square tiles. 11. The apparatus of claim 10, wherein at least one of the pixels in the predetermined spatial relationship with a tile is at a corner of the tile. 12. The apparatus of claim 10 or 11, wherein at least one of the pixels in the predetermined spatial relationship with a tile is at a corner of a neighboring tile. 13. The calculation means, in use, compares the pre-operation address of a pixel in the predetermined spatial relationship with the tile with the post-operation spacing to determine the horizontal and vertical compression of the tile due to the operation. Claim 10, 11 or 1 to be determined
2 devices. 14. Filtering each pixel in each tile in use, taking into account the vertical local compressibility of the neighboring tiles of the first type that are closest to each pixel and within the same sub-area when in use. Any one of claims 10 to 13
The device of paragraph. 15. Filtering each pixel in each tile in use, taking into account the horizontal local compressibility of the neighboring tiles of the first type that are closest to each pixel and in the same sub-area when in use. Any one of claims 10 to 14.
The device of paragraph. 16. The tile according to claim 9, wherein each tile includes 16 pixels arranged in 4 rows and 4 columns.
The device of paragraph.