RU2338332C2 - Method for block prediction using advanced direct prediction mode - Google Patents

Abstract

FIELD: computer engineering.

SUBSTANCE: forward and back image block motion vectors for B-frame are calculated by scaling the shifted block motion vector in subsequent base frame; previous and subsequent blocks are obtained using forward and back motion vectors respectively; and image block in current B-frame is predicted according to previous and subsequent blocks by using the difference in information about display order between current B-frame and previous base frame or subsequent base frame to which previous and subsequent blocks respectively belong.

EFFECT: improving accuracy of image block prediction and coding and decoding effectivness.

3 cl, 4 dwg

Description

BACKGROUND OF THE INVENTION

1. The technical field to which the invention relates.

The present invention relates to a moving picture coding system and, in particular, to a block prediction method using an advanced direct prediction mode for B-frames.

2. Description of the prior art

One of the advantages of using B-frames in a moving picture coding system is that the direct prediction mode, which does not introduce additional overhead information, is selected more often than other prediction modes (such as forward prediction, reverse prediction, bidirectional prediction, intra-frame prediction, etc. .). Therefore, using B-frames, and not just P-frames, it is possible to increase the efficiency of the moving picture coding system.

For B-frames, the block prediction method using the direct prediction mode reduces to converting the forward vector and backward vector into scaled versions of the displacement block motion vector in a subsequent reference frame for the direct prediction mode, to obtain two separate blocks with motion compensation using the above motion vectors and to obtain at the final stage a predicted block by averaging two blocks with motion compensation.

In more detail, the foregoing block prediction method using the direct prediction mode can be considered with reference to FIG.

1 is an image diagram for describing a block prediction method using a direct prediction mode in accordance with known technology. As can be seen from the illustration, the image circuit contains an I-frame (not shown) encoded with prediction only for decoded samples within the frame itself, P-frames P1, P4 and P7 encoded with inter-frame prediction for at most one motion vector over previously decoded reference frames , and B-frames B2, B3, B5 and B6, encoded using two blocks with inter-frame prediction on previously decoded reference frames.

In addition, for convenience, the parameters presented in FIG. 1 will be primarily described. TR _D is the time interval between the previous reference frame for the direct prediction mode (P1) and the subsequent reference frame for the direct prediction mode (P7); TR _B is the time interval between the previous reference frame for the direct prediction mode (P1) and the current B-frame (B5); MV is the motion vector of the offset block in the subsequent reference frame for the direct prediction mode (P7); MV _f is the forward motion vector in the direct prediction mode indicating the previous reference frame for the direct prediction mode, and MV _b is the forward motion vector in the direct prediction mode indicating the subsequent reference frame in the direct prediction mode. In this case, the previous reference frame for the direct prediction mode is the reference frame indicated by the motion vector of the offset block in the subsequent reference frame for the direct prediction mode.

Using the above parameters, the method for predicting a block in the direct prediction mode can be described as follows.

First of all, the forward motion vector in the direct prediction mode (MV _f ) is obtained from the motion vector (MV) of the biased block B _s in the subsequent reference frame for the direct prediction mode (P7) according to the formula (1)

In addition, the backward motion vector in direct prediction mode (MV _b ) is obtained from the motion vector (MV) of the displaced block B _s in a subsequent reference frame for the direct prediction mode (P7) using formula (2)

Thus, the motion of the blocks B _f and B _{b is} compensated by the motion vectors MV _f and MV _b calculated using formulas (1) and (2), after which these two blocks are averaged to obtain the prediction value B ' _{from the} current block B _s in the B-frame according to the formula (3)

However, in accordance with the known method for predicting a block in the direct prediction mode, the forward motion vector for the direct prediction mode is obtained from the displacement block motion vector in a subsequent reference frame for the direct prediction mode, as a result of which the obtained value will be only an approximate and not an exact motion vector of the current block frame.

In addition, in accordance with the known method for predicting a block in direct prediction mode, even if the reference frame is close in time to the B-frame and is very similar to the B-frame, the block prediction is performed using the average of two separate blocks with motion compensation excluding time interval between reference frames. Therefore, the accuracy of the predicted block is reduced.

In particular, in the sequence including a fading object, due to the fact that the brightness of solid B-frames can gradually decrease or gradually increase, the prediction value obtained by simple averaging of two blocks with motion compensation is very different from the original one, as a result of which the efficiency coding the entire system is greatly reduced.

SUMMARY OF THE INVENTION

Thus, it is an object of the present invention to provide a method for predicting a block in a direct prediction mode having a higher coding efficiency by obtaining a forward motion vector in a direct prediction mode of a displacement block motion vector in a subsequent reference frame in a direct prediction mode and obtaining a predicted block in B the frame currently being encoded using interpolation prediction over two separate blocks with motion compensation.

Another objective of the present invention is to provide a method for predicting a block in a direct prediction mode, capable of increasing the accuracy of a predicted block and coding efficiency by obtaining a forward motion vector in a direct prediction mode from a reference frame that is closest to the current B frame and by obtaining a predicted block in In-frame, which is currently encoded using interpolation prediction for two separate blocks with motion compensation.

To achieve the objectives of the present invention, as shown in the following examples of its implementation and detailed description, a block prediction method for an advanced direct prediction mode has been developed, comprising the following operations: the first operation is to obtain a forward motion vector in the direct prediction mode for a B-frame to be encoded ( or decoding); the second operation is to obtain a backward motion vector in direct prediction mode for the B-frame to be encoded (or decoded); the third operation is the receipt of two separate blocks with motion compensation by using the forward and backward motion vectors in the direct prediction mode obtained in the first and second operations; and the fourth operation is the prediction of the block of the B-frame to be encoded (or decoded) at the moment, using interpolation prediction for two separate blocks with motion compensation obtained in the third operation.

These and other objectives, features, aspects and advantages of the present invention will be more apparent from the following detailed description of the present invention, which is given with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which help to better understand the essence of the invention and are an integral part of this description, illustrate examples of the invention and together with the description to explain the principles underlying it.

The drawings show the following:

figure 1 presents a diagram illustrating a known method for predicting a block in direct prediction mode;

2 is a diagram illustrating a method for predicting a block in a direct prediction mode in accordance with the present invention;

3 is a diagram illustrating an interpolation prediction method in accordance with one embodiment of the present invention, and

4 is a diagram illustrating an interpolation prediction method in accordance with another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FOR CARRYING OUT THE INVENTION

The description contains detailed references to preferred embodiments of the present invention and their corresponding illustrations in the accompanying drawings.

In the direct prediction mode block prediction method of the present invention, the forward and backward motion vectors in the direct prediction mode are determined by the motion vector of the shifted block in the previous reference frame for the direct prediction mode, two motion compensation blocks are obtained using the above motion vectors, and finally by interpolating two blocks with motion compensation, a predicted block is obtained.

In addition, in the block prediction method using the direct prediction mode of the present invention, the backward motion vector is determined by the subsequent reference frame in the direct prediction mode, the forward motion vector in the direct prediction mode is determined by the reference frame closest to the current B-frame among the subsequent reference frames and motion-compensated blocks are obtained from the aforementioned motion vectors, and finally, a predicted block is obtained by interpolating two motion-compensated blocks.

The following is a description of an example embodiment of the present invention with reference to the accompanying illustrations.

2 is a diagram illustrating a method for predicting a block in the direct prediction mode of the present invention. As can be seen from the diagram, the image includes an I-frame (not shown), encoded with prediction only for decoded samples within the frame itself, P-frames P1, P4 and P7, encoded with inter-frame prediction when using at most one motion vector from previously decoded reference frames, and B-frames B2, OT, B5 and B6, encoded by two blocks with inter-frame prediction on previously decoded reference frames.

- вектор движения вперед в режиме прямого предсказания в направлении опорного кадра (Р4), ближайшего к текущему В-кадру, и MV_b - вектор движения назад в режиме прямого предсказания в направлении последующего опорного кадра для режима прямого предсказания (Р7).Further, for convenience, the first description of the parameters presented in figure 2. TR _D is the time interval between the previous reference frame for the direct prediction mode (P1) and the subsequent reference frame for the direct prediction mode (P7); TR _B is the time interval between the previous reference frame for the direct prediction mode (P1) and the current B-frame (B5); TR _N is the time interval between the reference frame (P4) closest to the current B-frame and the current B-frame (B5); MV is the motion vector of the offset block in the subsequent reference frame for the direct prediction mode (P7);

is the forward motion vector in the direct prediction mode in the direction of the reference frame (P4) closest to the current B-frame, and MV _b is the reverse motion vector in the direct prediction mode in the direction of the subsequent reference frame for the direct prediction mode (P7).

Currently, the motion vector (MV) of the biased block B _s in a subsequent reference frame for the direct prediction mode (P7) is obtained in the process of encoding (or decoding) a subsequent reference frame for the direct prediction mode before encoding (or decoding) the current B-frame.

направленный к опорному кадру (Р4), наиболее близкому по времени среди предыдущих опорных кадров, получают из уравнения (4)The foregoing direct prediction mode block prediction method of the present invention is described as follows. Forward motion vector

directed to the reference frame (P4), closest in time among the previous reference frames, obtained from equation (4)

In addition, the backward motion vector (MV _b ) indicating the subsequent reference frame in the direct prediction mode (P7) is obtained in the usual way using equation (2)

и MV_b, рассчитанным по уравнениям (2) и (4).Accordingly, motion compensation blocks B _f and B _b are obtained from motion vectors

and MV _b calculated according to equations (2) and (4).

для блока В_с получают по двум вышеупомянутым блокам с компенсацией движения B_f и В_b. В тот момент В-кадр может находиться ближе к тому кадру, который расположен между опорным кадром, содержащим блок с компенсацией движения B_f, и тем последующим опорным кадром для режима прямого предсказания, в котором находится блок с компенсацией движения В_b.On the other hand, the predicted value

for the block B _c is obtained by the above two motion-compensated blocks B _f and B _b. At that moment, the B-frame may be closer to that frame that is located between the reference frame containing the motion compensation block B _f and the subsequent reference frame for the direct prediction mode in which the motion compensation block B _{b is located} .

The block prediction method using the direct prediction mode of the present invention can be applied to FIGS. 1 and 2, and therefore, the reference frame containing the motion compensation block B _f is the previous reference frame for the direct prediction mode (for example, frame P1 in FIG. .1) or the reference frame closest to the B-frame (for example, frame P4 in FIG. 2).

In addition, in a sequence containing a fading object, the brightness of solid B-frames can gradually weaken or gradually increase, and therefore, the predicted value obtained by simple averaging of two blocks with motion compensation B _f and B _b , as is known technology is much different from the original value. As a result, the coding efficiency of the entire system is significantly reduced.

Therefore, to improve the accuracy of the block predicted in the direct prediction mode, the interpolation prediction is carried out in the block prediction method using the direct prediction mode of the present invention taking into account the time interval between the current B frame and the reference frame in which the block with motion compensation B _f ( that is, the previous reference frame for the direct prediction mode or the reference frame closest to the B-frame) and taking into account the time interval between the current B-frame and the subsequent reference frame for direct prediction mode.

As shown in FIG. 3, if the forward vector of the forward prediction mode is obtained using known means, the block with motion compensation B _f is in the previous reference frame for the direct prediction mode (P1), and the block with motion compensation B _b is in the subsequent reference frame for the direct prediction mode (P7), then interpolation prediction is performed according to equation (5). In this case, TR _D is the time interval between the previous reference frame for the direct prediction mode (P1) and the subsequent reference frame for the direct prediction mode (P7), and TR _B is the time interval between the previous reference frame for the direct prediction mode (P1) and current B frame (B5). In particular, the interpolation prediction method includes the same averaging calculations as the known means in case the B-frame is located in the center between the previous reference frame for the direct prediction mode and the subsequent reference frame for the direct prediction mode.

In addition, as follows from figure 4, in the case of obtaining a forward motion vector in direct prediction mode in accordance with the present invention, the motion compensation block B _f is located in the reference frame (P4) closest to the current B-frame, and the block with motion compensation In _b is in the subsequent reference frame for the direct prediction mode (P7). Therefore, the interpolation prediction is carried out according to equation (6). In this case, TR _D is the time interval between the previous reference frame for the direct prediction mode (P1) and the subsequent reference frame for the direct prediction mode (P7), TR _B is the time interval between the previous reference frame for the direct prediction mode (P1) and the current B-frame, and TR _N is the time interval between the reference frame (P4) closest to the current B-frame and the current B-frame.

On the other hand, corresponding frames can be represented using a frame sequence counter, i.e. display order information may be provided.

Therefore, equations (5) and (6) can be represented as equations (7) using frame order readout values that display information about the order of the respective frames. In this case, T _c - the count value of the order of frames, i.e., display order information assigned to the current B-frame; T _f - the value of the reference frame order, i.e. information about the display order assigned to the previous reference frame for the direct prediction mode, or the value of the ordinal frame count, i.e. information about the display order assigned to the reference frame closest to the B-frame, if the forward vector is calculated according to equation (4), and T _b is the value of the frame order reference, i.e. display order information assigned to a subsequent reference frame for the direct prediction mode.

As mentioned above, according to the present invention, the forward-motion forward vector in the direct prediction mode is obtained from the displacement block motion vector in a subsequent reference frame for the direct prediction mode, and the predicted block of the encoded B-frame is obtained by interpolation prediction of the time-compensated block values. Therefore, coding efficiency is improved compared to coding by known means.

In addition, according to the present invention, the forward-motion vector in direct prediction mode is obtained from the reference frame closest to the B-frame to be encoded (or decoded) at the moment and most similar to the B-frame, and the predicted B-frame block is obtained by applying interpolation prediction in blocks with motion compensation for the aforementioned forward and backward motion vectors in the direct prediction mode. Therefore, the accuracy of the predicted block as well as the coding efficiency can be improved.

Since this invention can be implemented in different ways, but without departing from its essence or essential features, it should be borne in mind that the above-described embodiments of the present invention are not limited to any details of the above description, unless otherwise indicated, but rather should be interpreted in a broad sense in accordance with the essence and scope of the invention, as defined by the attached claims, and, therefore, all changes and modifications that are within this ith formulas, or their equivalents, will be embraced by the claims.

Claims (3)

1. A method for predicting an image block in the current B-frame, comprising: calculating the forward and backward motion vectors of the image block in the current B-frame by scaling the motion vector of the displaced block in a subsequent reference frame; obtaining the previous and subsequent blocks using the forward and backward motion vectors, respectively, and predicting the image block in the current B-frame from the previous and subsequent blocks by using the difference in the display order information between the current B-frame and the previous reference frame or subsequent reference frame, which include the previous and subsequent blocks, respectively. 2. The method according to claim 1, in which each information about the display order is presented in the form of a sequence number of the frame. 3. The method according to claim 1, wherein the prediction operation predicts the image block in the current B-frame when the decoder is in direct prediction mode.

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