KR100359813B1 - Alternative Double Scan For Video Coding And Decoding - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double scan technique of image transform coefficients in a video compression encoding (decoding) system. In particular, the present invention relates to compression coding of an image (conversion coefficient) using a modified double scan. The present invention relates to a modified double scan method for reducing the number of bits.

In the present invention, as shown in Fig. 3, when scanning and transforming a transform coefficient of a 4x4 block B, when performing a double scan by dividing the block into two blocks, the order of the scan 301 for the first area is B01. → B02 → B11 → B12 → B03 → B13 → B23 → B33, and perform the scan 302 procedure for the other areas in the order of B00 → B10 → B20 → B21 → B22 → B30 → B31 → B32. By doing so, it is possible to scan signals in a distribution that cannot be efficiently scanned by the conventional double scan, and to modify the video compression encoding to reduce the number of bits, thereby improving the performance of the image data compression encoding. This is a double scan method.

Description

Alternative Double Scan For Video Coding And Decoding

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double scan technique of image transform coefficients in a video compression encoding (decoding) system. In particular, the present invention relates to compression coding of an image (conversion coefficient) using a modified double scan. The present invention relates to a modified double scan method for reducing the number of bits.

Various techniques and standards for compressing video or still images have been proposed, and the standards for compressing video and still images have the ultimate purpose of compressing and encoding video with more efficient and higher performance.

Currently, MPEG-1, MPEG-2, MPEG-4, and H.261, H.263, H.26L, etc. have been proposed or proposed (adopted) as standards related to video encoding of moving pictures and still images.

Like many international standards, the H.26L standard performs motion estimation and encodes the residual signal resulting from spatio-temporal transformation and zigzag scanning. ) May be performed based on encoding by a quantization process.

1 is a schematic block diagram of an encoder proposed by Telenor, which performs a spatiotemporal / spatial transform (e.g., a DCT transform) on an image input (INPUT) (101) and quantizes the transform coefficients. A variable length coding (VLC) 105 is performed by scanning the quantized transform coefficients using a single scan 103 or a double scan 104 to output a compression coded video signal (OUTPUT). .

In particular, in H.26L, the residual signal is divided into 4 × 4 blocks and scanned according to the appropriate conditions as a whole (Simple Scan), or divided into two areas (Double Scan) before quantization and Encoding is performed.

However, the reason for the double scan is that a variable length coding table (VLC Table) formed according to the characteristics of a single scan has a large number of non-zero coefficients due to the characteristics of the residual signal. This is because it is difficult to have a characteristic similar to that of a single scan of the residual signal through a double scan.

However, the dual scan having this purpose divides the transform coefficients distributed in a square into straight lines having a horizontal angle of 135 degrees and divides them into two regions in a diagonal direction.

The reason for doing this comes from the effort to divide the coefficients into two regions evenly as the distribution of transformation coefficients increases to the upper left.

For example, as shown in FIG. 2, when the 4 × 4 block B is examined, the larger the DC component is, the more the distribution coefficients are distributed toward the upper left corner B00.

(A) of FIG. 2 represents a conventional single scan, and (b) represents a conventional double scan.

In the case of a single scan, zigzag scanning is performed in the order indicated by the arrow 201 as shown in FIG.

That is, scanning of the conversion coefficient is performed in the order of B00 → B01 → B10 → B20 → B11 → B02 → B03 → B12 → B21 → B30 → B31 → B22 → B13 → B23 → B32 → B3 for the 4 × 4 block B. To do.

In the case of the double scan, scanning (202a, 202b) is divided into two areas along the diagonal line as shown in (b) of FIG.

The order of scanning 202a for one area is performed in the order of B00 → B01 → B02 → B12 → B22 → B03 → B13 → B23, and the order of scanning 202b for the other area is B10 → B20 →. B11 → B21 → B30 → B31 → B32 → B33.

However, since the region to be encoded is a block divided into 4 × 4, when divided into diagonal lines, both regions have an asymmetric structure.

However, it is assumed that the image to be encoded is not biased in the specific direction along the vertical direction and the horizontal direction.

Therefore, this asymmetric property may be inferior to the case of performing a double scan into an asymmetric region depending on the image distribution.

In order to overcome this situation, the necessity of complementing the double scan having an asymmetric geometry is raised.

According to the present invention, a method of compressing and encoding an image, when transforming and encoding an image by a block unit, transforms a transform coefficient scanning in a block unit to perform a quantization process following conversion and zigzag scanning to encode an image signal. The present invention provides a modified dual scan method for image compression encoding to reduce the number of bits required for image encoding by performing the conventional dual scan structure.

1 is a block diagram of an image encoder

Fig. 2 is a diagram for explaining single scan and double scan of 4x4 blocks.

3 is a view for explaining a modified double scan of the present invention.

4 is a diagram showing an example of a conversion coefficient for explaining the present invention;

FIG. 5 is a diagram showing the relationship between run length and level in the case of encoding using the conventional double scan and the double scan of the present invention with respect to the transform coefficient of FIG.

6 is a diagram showing the relationship between the present invention according to FIGS. 4 and 5 and the length of a string in the case of the conventional double-scan coding;

FIG. 7 is a view for explaining an example of the reduction of the number of bits in encoding by the present invention and a conventional double scan, taking three coefficients including DC as an example; FIG.

The single scan and double scan scan methods included in the predominant proposal based on the current H.26L standard scan blocks divided into 4 × 4 blocks in the direction shown in FIG.

As shown in Fig. 2, a single scan and a double scan are defined.

The two areas in the double scan are divided into two areas, bold and bold areas, as shown in (b).

However, as described above, when the area is divided according to the proposed double scan, the two divided areas have a geometrically asymmetric structure.

This asymmetric double scan has already been shown that the performance may be lowered according to the distribution of the image compared to the case where the double scan region is divided, unlike the proposed one.

Accordingly, the present invention proposes a modified double scan obtained by rotating the geometry of the proposed double scan region by 90 degrees, and in some cases, the proposed double scan and the modified double scan proposed in the present invention. Use it properly to increase performance.

That is, the modified double scan proposed in the present invention scans the proposed double scan by dividing the proposed double scan into an area obtained by rotating at an angle of 90 degrees.

As represented in Fig. 3, the scanning 301 and 302 of each area are divided into two areas for the 4x4 block B as follows.

First, the scanning 301 is performed on one region (bold in bold in the drawing) in the order of B01 → B02 → B11 → B12 → B03 → B13 → B23 → B33. 302) is executed in the order of B00-> B10-> B20-> B21-> B22-> B30-> B31-> B32.

Referring to the method of double scanning as shown in FIG. 3, the double scanning 301 in FIG. 3 is the same as that obtained by rotating the double scanning 202b by 90 degrees with respect to the diagonal line (B00-B33 axis) in FIG. It can be seen that the double scan 302 in FIG. 3 is the same as that obtained by rotating the double scan 301a by 90 degrees in FIG.

The transformation of the double scan proposed by Telenor into the modified double scan method obtained by rotating 90 degrees can be obtained simply by the transformation matrix rotating 90 degrees about the diagonal of the conventional double scan determinant.

If the double scan is performed as described above, it is possible to show better performance than the conventional double scan in the following cases.

In other words, consider a case where the transform coefficients are distributed as shown in FIG.

The results scanned by the conventional double scan method (Fig. 2 (b)) and the double scan method (Fig. 3) of the present invention are as shown in Fig. 5.

In FIG. 5, the level is fixed at '1' for comparison.

However, in all international video coding standards such as MPEG-1, MPEG-2, MPEG-4, H.261 and H.263, if the run length is longer for the same level, the corresponding symbol is used. The variable length coding table is defined to allocate a codeword having a longer length when coding is performed.

These characteristics are also the same in the current proposal as a standard for H.26L.

Therefore, even if you change the size of the level, the probability of the same result is very high.

Due to this characteristic, the result of FIG. 6 is obtained when only the length of the run corresponding to the present invention and the conventional scanning method is understood in FIG. 5.

As shown in FIG. 6, in the case of encoding by the conventional double scan method and the modified double scan method of the present invention, in the case of the conventional double scan, two runs having a length of '0' and '1' 1, 2 is 1, and 3 is 1

By the way, in the method proposed in the present invention, the lengths of '0' and '3' are the same as in the case of the conventional double scan, but two and one appear respectively, but the length of the lines is '2' One of length '1' will appear.

When these results are encoded according to the H.26L standard proposal (Telenor proposal), when encoded by the existing double scan, a total of 27 bits are required except for the bits used in the EOB, and the modified double scan of the present invention. In this case, since 25 bits are required, the number of bits of 2 bits can be reduced and the performance of compression coding can be improved.

This can be described more simply by taking three coefficients including DC as an example.

As shown in Fig. 7, in the case of A (0,0), which is a DC value, a region belonging to the existing method and the method of the present invention is different.

Therefore, when A (0,0) is '0', the next coefficient is A (1,0) in the conventional method, but A (0,1) in the proposed method.

By the way, Huffman Tables in all standards assign codewords of the same length to longer or longer lengths for larger levels.

Therefore, in the case of A (1,0)> A (0,1), the proposed modified double scan method of the present invention exhibits the same performance using relatively fewer bits than the conventional double scan method.

It is very easy to extend this method to other coefficients to find out if the proposed method is more efficient than the existing one.

According to the present invention, when zig-zag scanning of transform coefficients is performed in compression encoding by processing an image in units of blocks, it is possible to more efficiently scan a signal having a distribution that cannot be efficiently scanned by a conventional double scan. By reducing the number, it is expected to improve the performance of image data compression coding.

Claims (2)

In compression coding by transforming and quantizing and scanning a video signal in space and time, (a). The conversion coefficients of the video signal are processed in 4x4 block units (Bxy, x = 0-> 3, y = 0-> 3), and (b). (C) when the data scan in the 4x4 block is divided into two by dividing the block diagonal into two scans. The divided one region is Bxy [xy = 01,02,03,11,12,13,23,33] and the other region is Bxy [xy = 00,10,20,21,22,30,31, 33] A modified double scan method for image compression encoding, wherein the scan is zigzag divided. The method of claim 1, wherein the conversion coefficients of the video signal are processed in 4x4 block units (Bxy, x = 0 → 3, y = 0 → 3), and data scanning in the 4x4 block is performed by dividing the block diagonal. When performing double scan by dividing into two as a reference, the scanning sequence in the divided one area Bxy [xy = 01,02,03,11,12,13,23,33] is B01 → B02 → B11 → B12 → B03 → The scanning sequence from B13 → B23 → B33 and the other area Bxy [xy = 00,10,20,21,22,30,31,33] is B00 → B10 → B20 → B21 → B22 → B30 → B31 → B32. The modified double scan method for image compression encoding, characterized by being scanned.