JPH11168725A - Image encoding method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the compression efficiency of an encoded data string of an entire image by making data that is encoded only by image data of each overlapped part position of a block appear only once in an encoded data string and generating the encoded data string. SOLUTION: An overlapped part is set as one pixel and a refresh point which is indicated by hatched ○ is to be shared by four blocks. Further, the number of horizontal and vertical pixels are set as N1 and N2 respectively. Also, in pixels except the refresh points in the overlapped part, one-dimensional direction linear estimation that is horizontal or vertical can be applied and only those pixels of the overlapped part can be encoded and decoded. Then, the same result occurs between adjacent blocks, and data can be shared two blocks. Thus, encoded data per block that constitutes an encoded data string of the entire image can be encoded data which corresponds to a point in an (N1 -1)×(N2 -1) blocks and a refresh point becomes only a single pixel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image coding method, and more particularly to an image coding method with improved code compression efficiency.

[0002]

2. Description of the Related Art In encoding an image, the image is composed of one or more one-dimensional horizontal or vertical directions composed of a plurality of pixels.
In the case of dividing into two or more two-dimensional blocks in the horizontal and vertical directions or three-dimensional blocks in the horizontal, vertical and time or depth directions and compressing and encoding the blocks, it is common to divide the blocks without overlapping and to perform image encoding. However, there is also an encoding method for encoding by overlapping blocks as in the following example.

[0003] First, LOT (Lapped Orthogonal Transfo
rm), two-dimensional rectangular blocks are shifted half a block in the horizontal and vertical directions and overlapped without gaps (that is, one pixel belongs to four blocks), and orthogonal transformation is performed for each block. I have.

In a digital VTR, two-dimensional blocks adjacent to each other are overlapped by one pixel in the horizontal direction every other block for the purpose of restoring data when an error occurs during decoding. DCT
(Discrete Cosine Transform) has been reported.

[0005]

However, in these examples, each encoded data in the block is converted from all the pixels in the block, and in the example of the digital VTR, an image corresponding to the overlapping portion of the block is obtained. The data is encoded or recorded twice before being recorded or transmitted, thus causing redundancy. Moreover, there is no coded data that is converted only from the pixels located in the overlap portion of the block, and the coded data of the overlap portion of the block differs for each block, and may be unified at the time of recording or transmission. Can not.

In general, for example, when an image is divided into two-dimensional blocks in the horizontal and vertical directions, and plane prediction for predicting from pixels surrounding the pixel is used as prediction encoding used in the block, decoding is performed at the time of decoding. An initial value (refresh point) at the end points (pixels at the four corners) of the block is required. The same applies when the block is one-dimensional or three-dimensional. When the refresh point located at the end point of the block is directly coded, there is data that is coded independently from only the refresh point, and the refresh point can be restored using only the coded data. When the amount is compared with the amount of data per pixel, the amount is larger than the amount of data of the prediction error signal which is encoded data for pixels other than the end points.

In such encoding, if the blocks are divided and encoded without overlapping the blocks in accordance with general block encoding, the ratio of the initial value (refresh point) at the end point of the block on the screen becomes large. Would. That is, in performing such encoding, the problem is how to reduce the ratio of the encoded data at the refresh point.

An object of the present invention is to reduce the occupation rate of the coded data at the refresh point and to reduce the occupation rate of the entire image when performing block coding in which an image is divided into blocks and a refresh point is required in the block. It is an object of the present invention to provide an image coding method capable of improving the compression efficiency of a code when viewed.

[0009]

In order to achieve the above object, an image encoding method according to the present invention comprises the steps of: converting an image into one dimension in a horizontal or vertical direction; two dimensions in a horizontal and vertical direction; In an image encoding method for dividing into three-dimensional blocks in the depth direction and encoding pixel values included in the blocks in the blocks to generate an encoded data sequence of an image, the division into the plurality of blocks is performed by using The range of the end portion of the block determined according to the intra-block encoding algorithm to be performed, and there is data encoded from only the image data located at the end portion of the block, and the end of the block is formed only by the encoded data. As far as the image data located on the side is decodable, the blocks adjacent to each other are horizontally or vertically aligned in a one-dimensional block. In dimension block horizontal and /
Or, in a three-dimensional block, in a three-dimensional block, block division is performed in which horizontal and / or vertical and / or time or depth overlaps by a predetermined pixel, and the generation of the coded data sequence is performed at each overlapping portion of the block. This is characterized in that the encoded data sequence is generated such that data encoded from only the image data to be reproduced appears only once in the encoded data sequence.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below based on embodiments of the present invention with reference to the accompanying drawings. In block coding, the pixels at the boundary between adjacent blocks are shared between adjacent blocks as described in the related art, as pixels located on the edge side of the block including the refresh point in each block. be able to. However, if the blocks are simply overlapped and coded for each block, the image data in the overlapped portion of the block is coded twice, which is redundant.

[0011] In addition to the above recognition, the data encoded from only the pixels located on the edge side of the block including the refresh point can decode the image data located on the edge side of the block using only the encoded data. Focusing on this fact, in the present invention, an image is divided into blocks while allowing overlap between adjacent image blocks, and encoding is performed only on pixels included in the overlap portion with respect to the overlap portion in each block. At the same time, the coded data of the overlap portion is caused to appear only once in the coded data sequence, so that the number of pixels to be coded is not increased as compared with the case where the blocks are not overlapped.

In the case of plane prediction in predictive coding, for example, the refresh points at the end points of the required blocks can be used in common between adjacent blocks. Divide into blocks and perform predictive coding on pixels in each block other than the end points of the block, and make the coded data of the overlap part appear only once in the coded data sequence. Can improve the code compression rate.

Although the description overlaps with the above, the present invention
To put it concretely, in the present invention, a plurality of images are used.
Blocks (up to 3D blocks, the number of pixels in each dimension direction)
To N _n, N = 1, 2, 3).
Of blocks determined according to the encoding algorithm used
The range of the end side, located at the end side of the block
The encoded data exists only from the
The image located at the end of the block is
Adjacent to each other as long as image data can be decoded
T in the direction of dimension n_n(N = 1,2,3:
0 ≦ t_n≤N_n/ 2, t_nIs an integer, but t_nIs less
Are not 0 in one dimension direction).
Block to make a block
But the overlapping part of the block
From encoded image data only
In other words, the data is registered only once in the encoded data sequence.
Duplicate data has been eliminated to prevent it from appearing.

[0014] As a result, the encoded data constituting the encoded data string, specifically, in the case of coding by dividing a one-dimensional block consisting of N ₁ pixels (N ₁ -t ₁₎ of the pixel When encoding is performed by dividing a block into a two-dimensional block consisting of N ₁ × N ₂ pixels, (N ₁ −t ₁ ) × (N ₂ −
t ₂₎ when the block and is divided into three-dimensional block consisting of N ₁ × N ₂ × N ₃ pixel-encoded pixels _{(N 1 -t 1) × (} N 2 -t 2) × (N ₃ -t ₃₎ a block of pixels.

As a specific example to which the present invention is applied, one of the lossless compression coding methods for an image is to divide an image into a plurality of blocks, and for each of the divided blocks, a bidirectional prediction code Let's consider the case of performing conversion. The details of this encoding method are described in detail in the specification of a patent application (Japanese Patent Application No. 9-332806) “Predictive encoding method and decoding method” filed on the same date as the present application. I have.

An outline of the predictive encoding method will be described with reference to FIG. 1 in a case where an image is divided into one-dimensional blocks (N pixels) in the horizontal direction. In FIG. 1, x _i is a pixel to be processed, and x _i−1 and x _{i + 1} are pixels before and after it. In the present example, is carried out linear prediction from pixel x _i-1, x i _{+ 1} before and after the target pixel x _i as predictive coding. As shown in FIG. 1, the prediction coefficients from the preceding and succeeding pixels are both set to the same value α. The prediction error signal at this time is given by the following equation.

(Equation 1) However, the numerical values at both ends (x ₁ and x _N ) of the block are defined as initial values (refresh points) serving as references within the block.
The pixel value itself is to be encoded.

Also, when dividing into two-dimensional and three-dimensional blocks, prediction is performed by extending a one-dimensional prediction formula in each dimension direction, as described in the specification of the above-mentioned application. However, in the case of two dimensions and three dimensions, the prediction coefficient in each dimensional direction can be set to a different value for each dimensional direction.

[0018]

(Equation 2)

In this case, the refresh points are pixels located at the four corners of the two-dimensional block, and these pixels have the pixel values themselves as encoding targets as initial values.
In an example of such a lossless encoding method, each block is divided into two-dimensional blocks (for example, N ₁ (the number of pixels in the horizontal direction) = N ₂ (the number of pixels in the vertical direction) = 9) without overlapping (conventional). In such a case, the refresh points are four corner points of the two-dimensional block (shown by hatched circles) as shown in FIG. (The predictive coding outlined here is described in detail in the above-mentioned application specification.)

FIG. 3 shows a case where the above-described predictive coding is performed by overlapping adjacent blocks according to the present invention. In FIG. 3, the overlap portion is one pixel (t ₁ (the number of overlap pixels in the horizontal direction) = t ₂ (the number of overlap pixels in the vertical direction) = 1).
The refresh point (shown by a hatched circle) is shared by four blocks. Also, for pixels other than the refresh point in the overlap portion, linear prediction in the horizontal or vertical one-dimensional direction can be applied,
Encoding and decoding can be performed only from the pixels in the overlap portion. Therefore, the result is the same between adjacent blocks, and data can be shared by two blocks.

Focusing on the fact that data can be shared in this manner, the encoded data per block constituting the encoded data sequence of the entire image is represented by (N ₁ -1) × (N ₂ −
1) Coded data corresponding to a point in a block can be set, and a refresh point can be set to only one pixel (see FIG. 3). As a result, in the two-dimensional prediction, by making the blocks overlap, it is possible to reduce the number of refresh points constituting the encoded data sequence to about 1/4 of that in the case where the blocks do not overlap, as compared with the case where the blocks do not overlap. it can.

FIG. 4 shows another example of a predictive encoding method different from the one described above, where a one-dimensional predictive expression is used as in the above-described example (the example of FIGS. 2 and 3) in the case of blocking into two-dimensional blocks. A case is shown in which a method based on a two-dimensional prediction formula using independently determined prediction coefficients is not overlapped, instead of being extended into a two-dimensional prediction formula. In this example,
That is, in the method in which the prediction equation at the end point of the block is not a one-dimensional prediction equation, not only the four corner points of the two-dimensional block but also the end side of the block are used as the refresh point (indicated by a hatched circle) during decoding. All the points located at are required. Therefore, as shown in FIG. 4, if the blocks are divided into blocks (for example, N ₁ (the number of pixels in the horizontal direction) = N ₂ (the number of pixels in the vertical direction) = 9) and encoded without overlapping, the refresh The number of points is 2 (N ₁ + N ₂ -2) located at the end of the two-dimensional block.

On the other hand, according to the present invention, blocks adjacent to each other are overlapped, and the overlap portion is equivalent to one pixel (t ₁ (the number of overlap pixels in the horizontal direction) =
Assuming that t ₂ (the number of overlapping pixels in the vertical direction) = 1), as shown in FIG. 5, the refresh points at the four corners (shown by hatched circles) are four blocks, and the other refresh points are two blocks. Can be shared by By such sharing, 1 which constitutes the encoded data string of the entire image
The encoded data per block is represented by (N ₁ -1) × (N
₂ -1) can be coded data corresponding to a point in the block, the refresh point, it is possible to (N ₁ + N ₂ -3) pixels. As a result, the number of refresh points constituting the encoded data string can be reduced to about half by overlapping the blocks, as compared with the case where the overlap is not performed.

The description of the present invention with an example of the predictive encoding method has been finished above. Depending on the encoding algorithm used, a refresh point may be reached even further inside the block. In such a case, it is possible to allow overlapping between adjacent blocks within the range of the refresh point as a limit, thereby achieving data sharing. However, in order to avoid complication of the processing, overlapping exceeding half of the number of pixels in the horizontal and vertical directions constituting the block is not allowed.

The image encoding method of the present invention can be applied to moving images and still images used in televisions, films, computers, images used for printing, medical images (for example, CT (Computed Tomography), MRI (MRI)). Magnetic R
esonance Imaging), PET (Positron Emission Tomo)
graphy), SPECT (Singlephoton Emission Comput
ed Tomography), DSA (Digital Subtraction Angiog)
Of course, if the information to be handled is an image, such as an image (e.g., raphy) or an X-ray photograph), it can be applied regardless of the type. However, in the case of a three-dimensional image, a moving image such as a television image has three dimensions in the horizontal, vertical and temporal directions, whereas a three-dimensional image such as a medical tomographic image has three dimensions in the horizontal, vertical and depth directions.

Also, the examples in FIGS. 1 to 5 all show the case where bidirectional predictive coding in which refresh points exist symmetrically at the end side of a block is assumed. May be present on only one side or asymmetrically on the end side.

[0027]

According to the image encoding method of the present invention, when an image is divided into blocks and encoded in the blocks, adjacent blocks are overlapped, and each overlapped portion is different from other portions. Predictive coding is performed by coding independently and coding based on the pixels of the entire block except for the overlapped portion, and by allowing the coded data of the overlapped portion to appear only once in the coded data sequence of the entire image. For example, when a refresh point is required at the end of a block, the refresh point can be shared, and as a result, it is possible to improve the compression efficiency of the encoded data sequence of the entire image.

[Brief description of the drawings]

FIG. 1 shows a predictive encoding method when an image is divided into one-dimensional blocks in a horizontal direction.

FIG. 2 illustrates a case where a picture is divided into two-dimensional blocks without performing overlapping adjacent blocks when performing predictive encoding (conventional technique).

FIG. 3 shows a case where the image is divided into two-dimensional blocks to perform predictive encoding and blocks adjacent to each other are divided and overlapped (the present invention).

FIG. 4 illustrates a case where a picture is divided into two-dimensional blocks without overlapping overlapping blocks when performing predictive encoding (prior art).

FIG. 5 illustrates a case where an image is divided into two-dimensional blocks to perform predictive encoding and blocks adjacent to each other are divided and overlapped (the present invention).

 ────────────────────────────────────────────────── ─── Continuing from the front page (72) Inventor Haruo Okuda 1-10-11 Kinuta, Setagaya-ku, Tokyo Japan Broadcasting Corporation Broadcasting Research Institute

Claims (1)

[Claims] 1. An image is divided into a plurality of one-dimensional blocks in the horizontal or vertical direction, two dimensions in the horizontal and vertical directions, or three-dimensional blocks in the horizontal, vertical and time or depth directions, and pixel values included in the blocks. In the image encoding method of encoding an image in a block to generate an encoded data sequence of the image, the division into a plurality of blocks is a range of an end portion of a block determined according to an intra-block encoding algorithm to be used, There is data coded from only the image data located at the end of the block, and the image data located at the end of the block can be decoded only with the encoded data. Neighboring blocks are three-dimensional blocks in the horizontal or vertical direction for one-dimensional blocks, horizontally and / or vertically for two-dimensional blocks. Is a block division that overlaps by a predetermined pixel in the horizontal and / or vertical and / or time or depth direction. The generation of the encoded data sequence is performed by encoding only image data located in each overlapping portion of the block. An image coding method characterized by generating a coded data sequence in which each of the generated data appears only once in the coded data sequence.