KR100557576B1 - Method for prediction of picture motion vector - Google Patents

Abstract

The present invention discloses a video motion vector prediction method capable of improving coding efficiency by enabling macroblock values of a MULTI-HYPOTHRSIS video to be coded in the direct mode. The disclosed invention comprises the steps of: determining whether a macro block of a subsequence picture present at the same position as a macro block of a multi-hipartisan picture to be currently coded in the direct prediction mode has a unidirectional or bidirectional motion vector; Obtaining a time distance of a motion vector of a macro block of a subsequence picture when it is determined whether the unidirectional or bidirectional motion vector is present; Obtaining a time distance from a reference picture of a motion vector of the macroblock of the subsequence picture to a macroblock of the multi-high partition picture to be currently coded; And obtaining a macroblock prediction value of the multi-high-partisan picture to be currently coded by using a motion vector of the macro-block of the sub-sequence picture and each time distance, and averaging or interpolating the multi-high party to be currently coded. And obtaining a final macroblock prediction value of the system picture.

Motion Vectors, Macros, Hypatis, Subsequences, Prediction, Direct

Description

Picture motion vector prediction method {METHOD FOR PREDICTION OF PICTURE MOTION VECTOR}

1A and 1B are diagrams for explaining a prediction method in a direct mode of a bidirectional predictive coded picture according to the prior art.

2A and 2B are prediction methods when a sub-sequence macro block of a multi-hipartisan picture to be currently coded according to the present invention has one motion vector.

3A to 3C are prediction methods when a sub-sequence macro block of a multi-hipartisan picture to be currently coded according to the present invention has two motion vectors.

* Description of the symbols for the main parts of the drawings *

FMV: Forward Motion Vector BMV: Reverse Motion Vector

MH: Multi High Party Systems SH: Single High Party Systems

The present invention relates to a picture motion vector coding method. More specifically, the present invention relates to a picture motion vector coding method. More specifically, the present invention relates to a picture motion vector coding method. More specifically, the present invention relates to a picture motion vector coding method. A method for predicting a picture motion vector with improved coding efficiency by obtaining a prediction value of a macro block of a current multi-hi-patial picture by obtaining a time distance between each motion vector and a motion vector of a subsequent picture macroblock. will be.

Recently, technology for compressing and restoring a digital picture signal has been developed with the development of a picture transmission apparatus such as the Internet and IMT-2000. The world standard is MPEG related technology.

In general, when displaying a Bidirectionally Predictive coded picture, the picture is predicted through intra picture, forward, reverse, bidirectional, and direct modes. That is, in the bidirectional mode of the bidirectional predictive coded picture, the motion vector of the macroblock is obtained in the forward direction and the reverse direction, and then the average or interpolation operation of the macroblock predictive value for each direction is performed to obtain the macroblock predictive value of the bidirectional predictive coded picture. Obtain

However, in a multi-hypothesis picture, the bidirectional mode is subdivided to allow the macro block to have a forward / forward motion vector and a reverse / reverse motion vector in addition to having a forward / reverse motion vector.

In the case of the forward predictive encoded picture, the intra picture and the inter picture have an intra picture and the inter picture. In the case of a single high-partition picture, the picture has an intra picture, an inter picture, and a backward prediction mode.

Accordingly, the multi-high partition picture and the single high partition picture may be referred to as pictures of a broader concept including the bidirectional predictive coded picture and the forward predictive coded picture.

The present invention is a method of improving coding efficiency by applying a prediction technique of the bidirectional predictive coded picture to the multi-highpartisan picture and the single highpartisan picture.

 1A to 1B are diagrams for describing a prediction method in a direct mode of a bidirectional predictive coded picture according to the prior art.

As shown in FIG. 1A, with a forward motion vector of a macroblock of a coded subsequence picture having the same position as the macroblock of the bidirectional predictively coded picture to be currently coded to code the bidirectional predictive coded picture to be currently coded. A method of predicting a macroblock of a bidirectional predictive coded picture to be currently coded is shown.

As shown in the figure, when the macroblock of the subsequence picture present at the same position as the macroblock of the bidirectional predictive coded picture to be currently coded has one forward motion vector, The reverse direct motion vector is obtained. The equation is generally used in the direct prediction mode of Bidirectionally Predictive coded picture.

FMV_ _f = (FMV * TRmh) / TRd

FMV_ _b = FMV * (TRmh-TRd) / TRd ............ (Equation 1)

Here, a time distance between the motion vector of the macroblock of the subsequence picture, that is, the picture referenced by the macroblock of the subsequence picture, is TRd, and the reference picture and the bidirectional predictive coded picture to be currently coded. Represents the temporal distance TRmh.

As shown in FIG. 1B, when the macroblock of the subsequence picture present at the same position as the macroblock of the bidirectional predictively coded picture to be coded contains only the backward motion vector, The reverse direct motion vector is obtained. Similarly, the equation uses a method for obtaining a bidirectional predictive coded picture in the direct prediction mode.

BMV_ _b1 = (BMV * TRmh) / TRd

BMV_ _b2 = BMV * (TRmh-TRd) / TRd ............ (Equation 2) where

Here, TRd represents a motion vector of the macroblock of the subsequence picture present at the same position as the macroblock of the bidirectional predictive coded picture to be currently coded, that is, the temporal distance from the reference picture of the macroblock of the subsequence picture, TRmh represents the temporal distance between the macroblock reference picture of the subsequence picture and the bidirectional predictive coded picture to be currently coded.

However, the above-described coding method generally relates to a coding technique of a bidirectional predictive coded picture, which is a multi-high party picture using a subsequence picture having motion vectors of forward, bidirectional, forward / forward, and reverse / reverse directions. There is a limit to applying it to coding.

The present invention is a method of predicting a picture motion vector capable of improving the coding efficiency of a multi-high partition picture by extending the conventional bidirectional predictive coded picture coding technique to a multi-high partition picture having a unidirectional or bidirectional motion vector. The purpose is to provide.

Picture motion vector prediction method according to the present invention for achieving the above object,

Determining whether the macro block of the subsequence picture present at the same position as the macro block of the multi-high partition picture to be coded in the direct prediction mode has a unidirectional or bidirectional motion vector;

Obtaining a time distance of a motion vector of a macro block of a subsequence picture when it is determined whether the unidirectional or bidirectional motion vector is present;

Obtaining a time distance from a reference picture of a motion vector of the macroblock of the subsequence picture to a macroblock of the multi-high partition picture to be currently coded; And

The macroblock prediction values of the multi-high-partition pictures to be currently coded are obtained by using the motion vectors of the macro-blocks of the sub-sequence pictures and the respective time distances, and the averaged or interpolated operations are used to multi-party to be currently coded. And obtaining a final macroblock prediction value of the system picture.

Here, the macro block of the sub-sequence picture is either a macro block of a single high partition picture or a multi high partition picture, and after determining whether the macro block of the sub sequence picture has a unidirectional or bidirectional motion vector, If the macro block of the subsequence picture has only a forward motion vector, the current distance is determined by using the time distance of the forward motion vector, the picture referred to by the forward motion vector, and the time distance from the multi-high partition picture to be currently coded. It is characterized by predicting a macroblock value of a multi-hipartisan picture to be coded.

Further, after determining whether the macro block of the subsequence picture has a unidirectional or bidirectional motion vector, and when the macroblock of the subsequence picture has only a reverse motion vector, the time distance of the reverse motion vector and the reverse motion vector A macro block value of the current multi-coded high-pathy picture to be coded is predicted by using the reference picture and the time distance between the current multi-coded high-pathy picture.

In addition, after determining whether the macro block of the subsequence picture has a unidirectional or bidirectional motion vector, when the macro block of the subsequence picture has two first forward / second forward motion vectors, the first forward motion vector A pair of motion vectors are obtained by using a time distance of, a picture referred to by the first forward motion vector, and a time distance to the multi-high partition picture to be currently coded, and the time distance of the second forward motion vector Using a time distance between the picture referred to by the second forward motion vector and the multi-high partition picture to be currently coded, obtain another pair of motion vectors, and then estimate a macroblock prediction value of the multi-high partition picture to be currently coded. To obtain two prediction values by averaging and interpolating, and averaging them Characterized in that to obtain the value of the macro-block of a multi-party high cis-picture coding.

According to the present invention, coding efficiency can be improved by obtaining and coding a motion vector of various methods according to each direction in a direct prediction mode to code a multi-hipartisan picture to be coded.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2A and 2B are prediction methods when a sub-sequence macro block of a multi-hipartisan picture to be currently coded according to the present invention has one motion vector.

As shown in Fig. 2A, a macro block of a sub-sequence picture (single high partition picture or multi-high partition picture) existing at the same position as the macro block of the multi-high partition picture to be coded is one forward motion vector. In the case of having only, the macroblock value is predicted using the same prediction method of the conventional bidirectional predictive coded picture.

Since the prediction method in the direct mode applies the method described with reference to FIG. 1A when the macro block of the sub-sequence picture existing at the same position as the macro block of the multi-high-partisan picture to be coded goes only one forward motion vector, It demonstrates centering around a part distinguished below.

Therefore, using Equation 1 as described in Figure 1a

FMV_ _f = (FMV * TRmh) / TRd

FMV_ _b = FMV * (TRmh-TRd) / TRd ............ (Equation 1)

Here, the motion vector of the macroblock of the subsequence picture (SH or MH picture) existing at the same position as the macroblock of the multi-high-partisan picture to be coded, that is, the picture referred to by the subsequence picture macroblock. The temporal distance at is TRd, and represents the temporal distance TRmh between the reference picture and the current MH picture to be coded.

A macroblock motion vector of the subsequence picture is used to predict a forward macroblock value of the multi-high partition picture to be currently coded.

As shown in FIG. 2B, when the macro block of the sub-sequence picture (SH or MH picture) existing at the same position as the macro block of the multi-hipartisan picture to be coded currently has only the backward motion vector, As a result, a reverse direct motion vector and a reverse direct motion vector are obtained.

Since the prediction method in the direct mode applies the method described with reference to FIG. 1B when the macro block of the sub-sequence picture existing at the same position as the macro block of the multi-high-partisan picture to be coded goes only one reverse motion vector, It demonstrates centering around a part distinguished below.

BMV_ _b1 = (BMV * TRmh) / TRd

BMV_ _b2 = BMV * (TRmh-TRd) / TRd ............ (Equation 2)

Here, TRd refers to the backward motion vector of the macro block of the sub-sequence picture (SH or MH picture) existing at the same position as the macro block of the multi-high-partisan picture to be coded, that is, the sub-sequence picture macro block. The temporal distance between the pictures is shown, and TRmh represents the temporal distance between the picture referred to by the macro block of the subsequence picture and the multi-high-partisan picture to be currently coded.

Therefore, when the macro block of the sub-sequence picture, which is a single high or multi high partition picture, has only one motion vector in the forward or reverse direction, a forward or reverse motion vector is obtained in the direct prediction mode, and then the current coding is performed. The coding efficiency is improved by averaging or interpolating a macroblock value of a multi-hipartisan picture.

3A to 3C are prediction methods when a sub-sequence macro block of a multi-hipartisan picture to be currently coded according to the present invention has two motion vectors.

As shown in Fig. 3A, the macro blocks of a subsequence picture (single high partition picture or multi-high partition picture) present at the same position as the macro block of the multi-high partition picture to be coded are two forward / If FTR1d has forward motion vectors FMV1 and FMV2, FTR1d represents the time distance of forward motion vector FMV1 of the macro block of the subsequence picture, and FTR1mh is from forward motion vector FMV1 of the macro block of the subsequence picture. The distance to the multi-hipartisan picture to be coded is shown.

FTR2d represents the visual distance of the forward motion vector FMV2 of the macroblock of the subsequence picture, and FTR2mh represents the forward motion vector FMV2 of the macroblock of the subsequence picture from the multi-high party picture to be coded. Represents the time distance.

The equation for obtaining the motion vector based on the value defined above is as follows.

FMV1_ _f = (FMV1 * FTR1mh) / FTR1d

FMV1_ _b = FMV1 * (FTR1mh-TR1d) / FTR1d ............ (Equation 3)

FMV2_ _f = (FMV2 * FTR2mh) / FTR2d

FMV2_ _b = FMV2 * (FTR2mh-FTR2d) / FTR2d ............ (Equation 4)

Finding the current macro block in forward and backward directions of the multi-high party cis-picture coding motion vector one pairs (FMV1_ _f, FMV1_ _b) from the above equation, by using the FTR2d and FTR2mh another forward-backward motion vector one pairs (FMV2_ _f , FMV2_ _b )

The macroblock values for the two motion vector pairs obtained as described above are predicted by averaging or interpolating the two macroblock values of the current multi-high partition picture. The predicted values obtained here are averaged again to finally obtain the multi-high partition picture macroblock prediction values to be coded.

As shown in FIG. 3B, the macro block of the sub-sequence multi-highpartisan picture present at the same position as the macroblock of the multi-highpartisan picture to be coded currently has two forward / reverse motion vectors (FMV, BMV). If so, FTRd represents the time distance of the forward motion vector FMV of the macro block of the subsequence picture, and FTRmh represents the multi-high partition system to be coded from the forward motion vector FMV of the macro block of the subsequence picture. The time distance to the picture is shown.

And, BTRd represents the time distance of the backward motion vector BMV of the macro block of the subsequence picture, and BTRmh is from the backward motion vector BMV of the macro block of the subsequence picture to the multi-high-partisan picture to be coded. Represents the time distance.

The equation for obtaining the motion vector based on the value defined above is as follows.

FMV_ _f = (FMV * FTRmh) / FTRd

FMV_ _b = FMV * (FTRmh-FTRd) / FTRd ............ (Equation 5)

BMV_ _b1 = (BMV * BTRmh) / BTRd

BMV_ _b2 = BMV * (BTRmh-BTRd) / BTRd ............ (Equation 6)

Finding the current forward and reverse motion of the macroblock of the multi-high party cis-picture coding vector one pairs (FMV_ _f, FMV_ _b) from the above equation, by using the BTRd and BTRmh another forward and backward motion vectors one pairs ( BMV_ _f , BMV_ _b ) is obtained.

The macroblock values for the two motion vector pairs obtained as described above are predicted by averaging or interpolating the two macroblock values of the current multi-high partition picture. Here, the obtained prediction values are averaged again to finally obtain the multi-high partition picture macroblock prediction values to be coded.

As shown in FIG. 3C, the macro block of the sub-sequence multi-highpartisan picture present at the same position as the macroblock of the multi-highpartisan picture to be coded currently has two reverse / reverse motion vectors BMV1 and BMV2. If so, BTR1d represents the time distance of the backward motion vector BMV1 of the macro block of the subsequence picture, and BTR1mh is the multi-high-partisan picture to be currently coded from the backward motion vector BMV1 of the macroblock of the subsequence picture. Indicate the time distance to.

And BTR2d and BTR2mh represent the time distances of the backward BMV2 of the macroblock of the subsequence picture, and BTR2mh is the reverse motion vector BMV2 of the macroblock of the subsequence picture to the multi-high-partisan picture to be coded. Represents the time distance.

BMV1_ _b1 = (BMV1 * BTR1mh) / BTR1d

_{BMV1_ b2 = BMV1 * (BTR1mh-} BTR1d) / BTR1d ............ ( equation 7) where:

BMV2_ _b1 = (BMV2 * BTR2mh) / BTR2d

_{BMV2_ b2 = BMV2 * (BTR2mh-} BTR2d) / BTR2d ............ ( equation 8) where,

Finding the current macroblock in the direction opposite to the backward motion of the multi-high party cis-picture coding vector one pairs (BMV1_ _b1, BMV1_ _b2) from the above equation, by using the BTR2d and BTR2mh another direction opposite to the backward motion vector one pairs ( BMV2_ _{b1, b2} BMV2_) determined.

The macroblock values for the two motion vector pairs obtained as described above are predicted by averaging or interpolating the two macroblock values of the current multi-high partition picture. Here, the obtained prediction values are averaged again to finally obtain the multi-high partition picture macroblock prediction values to be coded.

As described in detail above, the present invention relates to a case in which a macroblock of a subsequence picture present at the same position as a multi-hipartisan picture macroblock to be coded has a motion vector not only in one direction but also in both directions in the direct prediction mode. In addition, since the prediction value of the multi-high partition macro block to be coded can be predicted, coding efficiency can be improved.

In addition, when the sub-sequence picture is a multi-high partition or a single high-partition picture, there is an advantage of predicting a macro block value of a multi-high partition picture to be coded using a motion vector of each macro block.

The present invention is not limited to the above-described embodiments, and various changes can be made by those skilled in the art without departing from the gist of the present invention as claimed in the following claims.

Claims (7)

Determining whether the macro block of the subsequence picture present at the same position as the macro block of the multi-high partition picture to be coded in the direct prediction mode has a unidirectional or bidirectional motion vector; Determining a time distance of a motion vector of a macroblock of a subsequence picture, when it is determined whether the unidirectional or bidirectional motion vector is present; Obtaining a time distance from a reference picture of a motion vector of the macroblock of the subsequence picture to a macroblock of the multi-high partition picture to be currently coded; And The macroblock prediction values of the multi-high-partition pictures to be currently coded are obtained by using the motion vectors of the macro-blocks of the sub-sequence pictures and the respective time distances, and the averaged or interpolated operations are used to multi-party to be currently coded. Obtaining a final macroblock prediction value of the system picture; Picture motion vector prediction method comprising a. The method of claim 1, The macro block of the sub-sequence picture is any one of a macro block of a single high partition picture or a multi high partition picture. The method of claim 1, After determining whether the macroblock of the subsequence picture has a unidirectional or bidirectional motion vector, and when the macroblock of the subsequence picture has only a forward motion vector, the time distance of the forward motion vector and the forward motion vector refer to it. And predicting a macro block value of the multi-high partition picture to be currently coded using a time distance between a picture and the multi-high partition picture to be currently coded. The method of claim 1, After determining whether the macroblock of the subsequence picture has a unidirectional or bidirectional motion vector, when the macroblock of the subsequence picture has only a reverse motion vector, the time distance of the reverse motion vector and the reverse motion vector refer to And predicting a macro block value of the multi-high partition picture to be currently coded using a time distance between a picture and the multi-high partition picture to be currently coded. The method of claim 1, After determining whether the macro block of the subsequence picture has a unidirectional or bidirectional motion vector, and if the macro block of the subsequence picture has two first forward / second forward motion vectors, A pair of motion vectors are obtained by using a time distance, a time referred to by the first forward motion vector, and a time distance from the multi-high partition picture to be currently coded, and a time distance of the second forward motion vector and the second A pair of motion vectors are obtained by using a picture referred to by a forward motion vector and the time distance between the multi-high partition picture to be currently coded, and the macroblock prediction values of the multi-high partition picture to be currently coded are obtained to average and interpolate. Compute two prediction values and average them again to get the final current coding A picture motion vector prediction method, comprising: obtaining a macroblock value of a tea high-patience picture. The method of claim 1, After determining whether the macroblock of the subsequence picture has a unidirectional or bidirectional motion vector, and when the macroblock of the subsequence picture has two forward / reverse motion vectors, the time distance of the forward motion vector and the forward motion A pair of motion vectors are obtained by using a picture referenced by a vector and a time distance between the multi-high partition picture to be currently coded, a time distance of the backward motion vector and a picture referred to by the backward motion vector, and the current coded image. A pair of motion vectors are obtained by using a time distance to a multi-history system picture to obtain a macroblock prediction value of the multi-high-party system picture to be currently coded, averaged and interpolated, and two prediction values are obtained and averaged again. The final number of multi-hipartisan pictures to be coded A picture motion vector prediction method, characterized by obtaining a black block value. The method of claim 1, After determining whether the macro block of the subsequence picture has a unidirectional or bidirectional motion vector, and if the macro block of the subsequence picture has two first reverse / second reverse motion vectors, A pair of motion vectors are obtained by using a time distance, a time referred to by the first reverse motion vector, and a time distance from the multi-high partition picture to be currently coded, and a time distance of the second reverse motion vector and the second A pair of motion vectors are obtained by using a picture referred to by a backward motion vector and the time distance between the multi-high partition picture to be currently coded, and the macroblock prediction values of the multi-high partition picture to be currently coded are obtained to average and interpolate. Compute two prediction values and average them again to get the final current coding Picture motion vector prediction method, characterized in that to obtain the value of the macroblock tea party high cis-picture.

Images