JP3148751B2 - Video encoding device and video decoding device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention belongs to the field of digital image processing, and relates to a moving picture encoding apparatus for encoding image data with high efficiency and a moving picture decoding apparatus for decoding encoded data.

[0002]

2. Description of the Related Art In image coding, a method of combining different moving image sequences has been studied. In the document “Image Coding Using Hierarchical Expressions and Multiple Templates” (IEICE Technical Report IE94-159, pp99-106 (1995)), a moving image sequence of a background moving image and a foreground component moving image ( For example, a method is described in which a new sequence is created by superimposing a human image or a video of a fish cut out by the chroma key technique.

[0003] In addition, a document "temporal scalability based on image contents"("TemporalScalability")
based on image content ",
ISO / IEC / JTC1 / SC29 / WG11 MP
EG95 / 211 (1995)) describes a method of creating a new sequence by superimposing a moving image sequence of a component moving image having a high frame rate on a moving image sequence having a low frame rate.

In this method, as shown in FIG. 15, predictive coding is performed at a low frame rate in a lower layer.
In the upper layer, predictive coding is performed at a high frame rate only for the selected region (dotted portion). However, the image frame decoded up to the upper layer can be obtained by superimposing the image frame decoded at the lower layer and the area decoded at the upper layer.

A frame coded in the lower layer is not coded in the upper layer, and the decoded image of the lower layer is copied and used as it is. Also, it is assumed that a part that attracts the viewer's attention, such as a person part, is selected as the selected area.

FIG. 11 shows a block diagram of a conventional method. First, on the encoding side of the conventional method, the input moving image is frame-thinned by the first frame dropping unit 1101 and the second frame dropping unit 1102, and the frame rate is set to be equal to or less than the frame rate of the input image. This is input to section 1103 and lower layer coding section 1104. Here, it is assumed that the frame rate of the upper layer is equal to or higher than the frame rate of the lower layer.

[0007] The lower layer coding section 1104 codes the entire input moving image. As the encoding method,
For example, MPEG or H.264. H.261 or the like is used. In the lower layer encoding section 1104, a decoded image of the lower layer is created and used for predictive encoding, and is input to the superimposing section 1105 at the same time.

In the upper layer encoding section 1103 of FIG. 11, only the selected area of the input moving image is encoded.
Again, MPEG and H.264. Although a moving picture coding international standardization method such as H.261 is used, only the selected area is coded based on the area information. However, frames encoded in the lower layer are not encoded in the upper layer.

The area information is information indicating a selected area such as a person, and is, for example, a binary image having a value of 1 at the position of the selected area and a value of 0 at other positions. Upper layer coding section 1103 also decodes only the selected area of the moving image,
This is input to superimposition section 1105.

[0010] In the area information encoding unit 1106, the area information is encoded using a chain code or the like. Superposition unit 1
105 outputs the decoded image of the lower layer when the lower layer frame is encoded in the superimposition target frame. When the lower layer frame is not encoded in the superimposition target frame, a moving image is output using two encoded lower layer decoded images before and after the superimposition target frame and one upper layer decoded image.

[0011] The two lower frame image frames are before and after the upper layer frame. The moving image created here is input to the upper layer encoding unit 1103 and used for predictive encoding. The image creation method in the superimposing unit 1105 is as follows.

First, two lower layer interpolation images are created. The decoded image of the lower layer at time t is B
(X, y, t) (where x and y are coordinates representing pixel positions in space), the times of the two lower layers are t1 and t2, respectively, and the times of the upper layers are t3 (where t is t).
1 <t3 <t2), the interpolated pixel I (x, y, t3) at time t3 is calculated by the following equation (1).

I (x, y, t3) = [(t2-t3) B (x, y, t1) + (t3-t1) B (x, y, t2)] / (t2-t1) (1) Next, the decoded image E of the upper layer is superimposed on the interpolated image I obtained by the above equation (1). For this purpose, the area information M (x,
Weight information W (x, y, t) for superimposition is created from y, t), and a superimposed image S is obtained by the following equation (2).

S (x, y, t) = [1-W (x, y, t)] I (x, y, t) + E (x, y, t) W (x, y, t) (2) Here, the region information M (x, y, t) is a binary image having a value of 1 inside the selected region and a value of 0 outside the selected region. By performing this, weight information W (x, y, t) can be obtained. That is, the weight information W (x, y, t) takes a value of 1 inside the selected area, 0 outside the selected area, and 0 to 1 at the boundary of the selected area.

The above is the description of the image creating method in the superimposing unit 1105. The coded data coded by the lower layer coding unit 1104, the upper layer coding unit 1103, and the area information coding unit 1106 are integrated by a coded data integration unit (not shown) and transmitted or stored.

Next, on the decoding side of the conventional method, the coded data is decomposed into coded data of a lower layer, coded data of an upper layer, and coded data of area information by a coded data decomposing unit (not shown). Is done. These encoded data are, as shown in FIG. 11, a lower layer decoding unit 1108,
Upper layer decoding section 1107 and area information decoding section 1109
Is decrypted by

The decoding-side superimposing section 1110 is composed of the same device as the encoding-side superimposing section 1105, uses the lower layer decoded image and the upper layer decoded image, and uses the same method as that described in the description of the encoding side. Images are superimposed. The moving image superimposed here is displayed on the display and input to the upper layer decoding unit 1107 to be used for prediction of the upper layer.

Here, the decoding apparatus for decoding both the lower layer and the upper layer has been described. However, if the decoding apparatus includes only the decoding section for the lower layer, the upper layer encoding section 1107 and the superimposing section 1110 are unnecessary. Yes, a part of the encoded data can be reproduced with a small hardware scale.

At this time, since the frame rates of the lower layer and the upper layer are different, the lower layer corresponding to the upper layer needs to be synthesized from the temporally preceding and succeeding lower layer frames. However, when an output image is obtained from two lower layer decoded images and one upper layer decoded image, the output image is synthesized by interpolation of the two lower layers. Therefore, when the position of the selected region changes over time, A large distortion occurs around the selected area, and the image quality is greatly deteriorated.

[0020] This is described in the document "Temporal Scalability based on image contents"("TemporalScalabilit").
y algorithmic based on imag
content ”, ISO / IEC / JTC1 / SC
29 / WG11 MPEG95 / 0377 (199
5)) and the like.

FIG. 14 illustrates a method for solving this problem shown in the above-mentioned document. In FIG. 14A,
Images A and C are two decoded images of the lower layer, image B is a decoded image of the upper layer, and the display time order is A, B, C. However, the selected area is indicated by oblique lines.

Since only the selected area is coded in the upper layer, the area outside the selected area is indicated by a broken line. Since the selection area is moving in the direction of the arrow in the figure, images A and C
In the interpolated image obtained from the above, two selected areas are overlapped as in a halftone dot portion in FIG. Further, image B
Is superimposed using Equation (2), the output image becomes
As shown in (c), an image in which the three selected areas overlap is obtained.

In particular, around the selected area of the upper layer (outside)
In addition, the selected area of the lower layer appears as an afterimage, and the image quality is greatly deteriorated. The entire moving image does not have the above distortion when only the lower layer is displayed, and the above distortion appears when the superimposed image of the upper layer and the lower layer is displayed. Image quality is greatly deteriorated.

However, the halftone dot on the left side of FIG.
Since the halftone portion on the right side in FIG. 14C can be obtained from the image A, the distortion can be eliminated by using the lower layer thus synthesized.

FIG. 12 is a block diagram of a conventional image superimposing apparatus disclosed in the above-mentioned document. The first area extraction unit 1201 in FIG. 12 extracts an area that is the first area and is not the second area from the first area information of the lower layer and the second area information of the lower layer.

In FIG. 13A, the first area information is represented by a dotted line (the inside of the dotted line has a value of 0, and the outside of the dotted line has a value of 1). Similarly, the second area information is represented by a broken line. Then, the region extracted by the first region extraction unit 1201 is a hatched portion in FIG.

The second area extracting unit 1202 in FIG. 12 extracts an area that is the second area and is not the first area from the first area information of the lower layer and the second area information of the lower layer. I do. In the case of FIG. 13A, a halftone dot portion is extracted.

A controller 1203 shown in FIG. 12 is a part that controls the switch 1204 based on the outputs of the first area extraction unit 1201 and the second area extraction unit 1202. That is, when the target pixel position is only in the first region, the switch 1204 is connected to the second decoded image side, and when the target pixel position is only in the second region, the switch 1204 is connected to the first decoded image. The switch is connected to the image side, and otherwise, the switch 1204 is connected to the output from the interpolation image creation unit 1205.

The interpolated image creating section 1205 of FIG. 12 calculates an interpolated image of the first decoded image of the lower layer and the second decoded image of the lower layer according to equation (1). However,
In equation (1), B (x, y, t1) is the first decoded image, B (x, y, t2) is the second decoded image, and I (x,
(y, t3) is the interpolation image, and t1, t2, and t3 are the times of the first decoded image, the second decoded image, and the interpolated image, respectively.

As described above, an image is created.
For example, in the case of FIG. 13A, the second decoded image is used in the shaded area, so that the background pixel outside the selected area appears, and in the halftone dot area, the first decoded image is used. , And an interpolated image of the first decoded image and the second decoded image appears in other portions.

Since the decoded image of the upper layer is superimposed on the image created in this manner by the weighted averaging unit 1206 in FIG. 12, the superimposed image is selected as shown in FIG. There is no afterimage around the shaded area) and an image with little distortion can be obtained. Weighted average section 1206 in FIG.
Superimposes the composite image and the decoded image of the upper layer by a weighted average.

[0032]

However, the above-described conventional apparatus has the following problems.

(1) When the degree of shape change due to the movement of the component area is small, it is not possible to expect a large improvement in image quality by the conventional method, and it is also necessary to use the front and rear corresponding to the component shape of the upper layer.
Since it is necessary to encode two pieces of shape information, the amount of codes that can be used for encoding texture information is relatively reduced, resulting in a problem (first problem) that image quality is reduced.

(2) The conventional method is effective when the component region moves to one side, but when the component image moves in a reciprocating manner, the information behind the component can be obtained in principle. There is a problem that the image quality cannot be improved (second problem). 8 and 10 are diagrams for explaining this problem. For example, a background image of a region where the component image regions in images A and C of FIG. 10 overlap (a hatched region in FIG. 8)
Cannot be obtained from the images A and C.

(3) In the conventional method, a lower layer temporally preceding and succeeding the image of the upper layer is required. One of the lower layer frames is placed at the beginning or end of an image sequence or before or after a scene change. It may not be present. Therefore, there is a problem that the image quality is not improved around the component image (third problem).

(4) The conventional method uses the 4 method shown in FIG.
It is necessary to selectively switch the interpolation process for each of the regions, and there is a problem that the process becomes complicated (fourth problem).

The present invention has been made in view of the third problem in particular. Even when one of the lower layer frames temporally preceding and lower than the image of the upper layer does not exist, the decoded image is decoded. It is an object of the present invention to provide a moving picture coding apparatus and a moving picture decoding apparatus capable of reducing the deterioration of the quality of a moving picture.

[0038]

According to a first aspect of the present invention, there is provided a moving picture coding apparatus comprising: means for separating one moving picture sequence into a lower layer having a lower frame rate and an upper layer having a higher frame rate; In the lower layer,
A lower layer encoding unit that encodes the entire image of the moving image sequence; an upper layer encoding unit that encodes a partial region of the image of the moving image sequence as a component image in the upper layer; If the area information encoding means for encoding region information of a part area shape of the sequence of images, the lower layer frame temporally corresponding to said higher layer frame does not exist, temporally corresponding to said upper layer frame The lower layer frame to be
Superimposing means for generating a background image using a lower layer frame existing before or after it temporally and superimposing the component image of the upper layer frame on the background image, wherein the image created by the superimposing means is provided. A predictive coding of the upper layer using the upper layer frame when the lower layer frame exists only temporally before the upper layer frame. Partial region of an image of the moving image sequence in a lower layer frame existing temporally before
Is generated by interpolating the inside of the component image area corresponding to the background image using the pixel values around it.

A moving picture coding apparatus according to a second aspect of the present invention includes means for separating one moving picture sequence into a lower layer having a lower frame rate and an upper layer having a higher frame rate. Lower layer encoding means for encoding the entire image of the moving image sequence,
In the upper layer, upper layer encoding means for encoding a partial region of the image of the moving image sequence as a component image, and region information for encoding region information indicating a partial region shape of the image of the moving image sequence encoding means, wherein when the lower layer frame to the higher temporally corresponding to the layer frame does not exist, time said upper layer frame
The lower layer frame corresponding to, the using lower layer frames existing temporally before or after, to produce a background image, and a superimposing means for superimposing a part image of the upper layer frame in the background image A moving image encoding apparatus that predictively encodes the upper layer by using an image created by the superimposing unit, wherein the superimposing unit is configured to perform an operation when the lower layer frame is an upper layer frame.
If only present after between manner, before the lower layer frame existing temporally after the upper layer frame
The background image is generated by interpolating the inside of a component image area corresponding to a partial area of the image of the moving image sequence using pixel values around the part image area.

In the moving picture coding apparatus according to the third invention of the present application, the component image area of the lower layer frame that cannot be covered by the component image of the upper layer frame is
If the value is smaller than a predetermined threshold value, the component image area of the upper layer
It is characterized in that it is extended to include an image area .

A moving picture decoding apparatus according to a fourth aspect of the present invention comprises a lower layer decoding means for decoding lower layer coded data obtained by coding an entire picture of a moving picture sequence at a low frame rate, and Upper layer decoding means for decoding encoded data of an upper layer obtained by encoding a partial region of an image of a moving image sequence as a component image, and region information indicating a partial region shape of the image of the moving image sequence is encoded. an area information decoding means for decoding the encoded data of the area information, the time to the higher layer frame
When the lower layer frame corresponding to specifically absent, the lower layer frame temporally corresponding to said upper layer frame, using the lower layer frames existing temporally before or after, to produce a background image, the Superimposing means for superimposing a component image of the upper layer frame on a background image, wherein the image created by the superimposing means is displayed on a display. If there exists only temporally before the upper layer frame, put the lower layer frame existing temporally before the upper layer frame
The background image is generated by interpolating the inside of a component image area corresponding to a partial area of the image of the moving image sequence using pixel values around the part image area. .

A moving picture decoding apparatus according to a fifth aspect of the present invention comprises a lower layer decoding means for decoding lower layer coded data obtained by coding an entire picture of a moving picture sequence at a low frame rate, and a high frame rate Upper layer decoding means for decoding encoded data of an upper layer obtained by encoding a partial region of an image of a moving image sequence as a component image, and region information indicating a partial region shape of the image of the moving image sequence is encoded. an area information decoding means for decoding the encoded data of the area information, the time to the higher layer frame
When the lower layer frame corresponding to specifically absent, the lower layer frame temporally corresponding to said upper layer frame, using the lower layer frames existing temporally before or after, to produce a background image, the Superimposing means for superimposing a component image of the upper layer frame on a background image, wherein the moving image decoding apparatus displays an image created by the superimposing means on a display, wherein the superimposing means comprises the lower layer frame Is present only temporally after the upper layer frame, the lower layer frame temporally existing after the upper layer frame .
The background image is generated by interpolating the inside of a component image area corresponding to a partial area of the image of the moving image sequence using pixel values around the part image area. .

[0043]

[0044]

Embodiments of the present invention will be described below in detail with reference to the drawings. The moving picture coding apparatus and the moving picture decoding apparatus according to the present invention have a feature in a portion corresponding to the image superimposing units 1105 and 1110 of the conventional apparatus shown in FIG. 11, and synthesizes a lower layer frame. When superimposing the lower layer and the upper layer, distortion of an image such as an afterimage generated around the selected area of the upper layer is visually suppressed.

Hereinafter, a first embodiment of the present invention will be described. The moving picture coding apparatus and the moving picture decoding apparatus according to the present embodiment are for solving the first problem described above, and are different from the conventional apparatus shown in FIG. , And an image superimposing unit shown in FIG.

When the frame corresponding to the upper layer of one moving image sequence does not exist on the lower layer side, the image superimposing section interpolates the frame of the lower layer, and sets the frame obtained by this interpolation as a background to the upper layer. An interpolated image (image information) is obtained by superimposing the component areas of the layer. The interpolated image is used for prediction encoding / decoding of the upper layer. Hereinafter, the apparatus according to the present embodiment will be described focusing on the image superimposing unit.

Here, in FIG. 1, the first area extracting unit 101 determines that the first area is not the second area from the first area information of the lower layer and the second area information of the lower layer. Extract the region. Specifically, in FIG. 13A, the first area information is represented by a dotted line (the inside of the dotted line has a value of 0, and the outside of the dotted line has a value of 1), and similarly, the second area information is represented by a broken line. In other words, the region extracted by the first region extracting unit 101 is a region represented by a hatched portion.

The second area extracting unit 102 in FIG. 1 extracts an area that is the second area and is not the first area from the first area information of the lower layer and the second area information of the lower layer. . In the case of FIG. 13A, a halftone dot portion is extracted.

The controller 103 shown in FIG. 1 controls the switch 104 based on the outputs of the first area extraction unit 101 and the second area extraction unit 102. That is,
If the target pixel position is only in the first area, switch 1
04 is connected to the second decoded image side, and
In the case of only the region of (1), the switch 104 is connected to the first decoding side image. In other cases, the switch 104 is connected to the output from the interpolation image creation unit 105.

The interpolated image creating unit 105 in FIG. 1 converts the interpolated image of the first decoded image of the lower layer and the second decoded image of the lower layer in accordance with the equation (1) described in [Conventional Art] above. calculate.

However, in equation (1), B (x, y,
t1) is a first decoded image, B (x, y, t2) is a second decoded image, I (x, y, t3) is a decoded image,
1, 1 and 2 are the times of the first decoded image, the second decoded image and the interpolated image, respectively.

The weighted averaging unit 106 in FIG. 1 superimposes the interpolated image created according to the above equation (2) and the decoded image of the upper layer. The background interpolation determination unit 107 shown in FIG. 1 is based on three types of area information, ie, lower layer first area information, lower layer second area information, and upper layer area information.
Depending on the size of the area where the upper layer indicated by the halftone dot in FIG. 14C cannot cover the two lower layer areas (that is, the lower layer component area appearing as the background),
It is determined whether or not to perform a combining process for suppressing the occurrence of distortion such as the afterimage.

When the area is larger than the predetermined threshold value, the switch 108 is connected to the left side (the output side of the switch 104), and the background is interpolated by performing the synthesis processing. That is, a frame obtained by performing weighted averaging of the lower layer and a frame of the lower layer are subjected to background interpolation to generate image information for predictive encoding / decoding of the upper layer.

On the other hand, when the area is equal to or smaller than the predetermined threshold value, the switch 108 is set to the right side (the interpolation image creation unit 105
, And the output of the interpolation image creation unit 105 is used as a lower layer to be combined with an upper layer. That is, the interpolation image creation unit 105 gives an image obtained by performing weighted averaging of the lower layers to the weighted averaging unit 106 via the switch 108.

Then, the weighted averaging unit 106 superimposes the image on the upper layer with the image as a background, and generates image information for predictive encoding / decoding of the upper layer. In this case (when the area is equal to or smaller than a predetermined threshold), the apparatus of the present embodiment does not use both the first area information and the second area information of the lower layer, and thus these pieces of information are not encoded. Thereby, the code amount for the area information can be saved.

FIG. 6 is a block diagram showing the configuration of the background interpolation judging section 107 shown in FIG. In the present embodiment, the determination as to whether or not to perform the synthesizing process is made based on the size of the halftone dot portion in FIG. 14C. As another method for realizing this, for example, A method using the area of the region may be used.

The area measuring unit 601 shown in FIG. 6 is for calculating the area. Fr (A) indicates the part area (foreground area) of the screen A in FIG. 14A, and Br indicates the background area of the part.
When (A) is set, the area can be expressed as {Fr (A) ∪Fr (C)｝ ∩Br (B) (3). Here, '∪' in this expression indicates the knot of the set, and '∩' indicates the intersection of the set.

The area of the region can be represented by the number of pixels of the region represented by the equation (3). Alternatively, for the area, a method of normalizing the number of pixels of the region with the number of pixels of the entire image can be considered.

Further, in addition to the area, the peripheral length of the area, the area of a circumscribed rectangle of the area, and the like can be considered. These values are, like the calculation of the area, the number of pixels of the entire screen, It is necessary to normalize using the size and the like.

As illustrated in FIG. 14, Fr
(A) When the entire region of Fr (C) (Fr (D)) (Fr (D)) is included in Fr (C), the region may be obtained using the above equation (3). Generally, the area is expressed as {Fr (A)} Fr (C)｝ ∩Br (D)｝ ∩Br (B) (4).

The comparison / determination unit 602 in FIG.
01 is compared with a predetermined threshold value (predetermined threshold value). If the area is larger than the threshold value, the switch 108 shown in FIG. The synthesizing process is performed.

If the area is not larger than the threshold value, the switch 108 is turned on by the interpolation image generator 10 shown in FIG.
5 and the interpolated image calculated according to the equation (1) without performing the synthesizing process is provided to the weighted averaging unit 106.

Up to this point, the interpolation image creation unit 105 shown in FIG.
Is used to create an interpolated image using equation (1), but instead of creating this interpolated image, one of the preceding and following lower layer frames may be directly output from the interpolated image creating unit 105.

For example, the time of the two lower layers is t1, t2, and the time of the upper layer is t3 (where t1
<T3 <t2), when using a pixel of a lower layer frame temporally closer to the current upper layer frame, the interpolation pixel I (x, y, t3) is calculated by the following equation (5a) or (5b). Calculate by

When t3-t1 <t2-t3 I (x, y, t3) = B (x, y, t1) (5a) When t3-t1> t2-t3 I (x, y, t3) = B (x, y, t2) (5b) In this case, the distortion area (that is, the area interpolated by the background interpolation) indicated by the halftone dot part in FIG. It looks like a dot. Therefore, the background interpolation determination unit 1 shown in FIG.
As the area used for the determination in 07, the halftone dot part in FIG. 16 is used.

Using the same symbols as in equation (3), the area (dotted portion in FIG. 16) is represented by the following equation (6).

｛Fr (A) ∩Br (D)｝ ∩Br (B) (6) By the way, if the background part is temporally changing, the above method cannot be used to successfully combine lower layers. There is.
In such a case, Br in FIG.
For the area (A), the pixel values of the image C are copied,
For the Fr (A) region, the background can be simply synthesized by interpolating the pixel values using the pixel values around Fr (A).

The configuration of the image superimposing unit for realizing this method is obtained by replacing the configuration surrounded by the two-dot chain line in FIG. 1 with the configuration shown in FIG. However, it is assumed that there is no input of upper layer area information. Here, the selecting unit 1 shown in FIG.
A step 801 selects a frame close to the current upper layer frame from the two lower layer frames.

The area information selected by the selection section 1801 is input to the controller 1802 and the interpolation section 1804, and the decoded image (pixel information) is input to the switch 1803.

The controller 1802 includes a switch 180
3 if the pixel of the image of the lower layer to be synthesized is inside the area (for example, Fr (A)),
If it is outside the area (for example, Br (A)), the pixel value of the decoded image is given to the interpolation unit 1804.

The interpolation unit 1804 obtains the pixel value inside the area by interpolation from the surrounding pixel values. Since this interpolation process is performed using background information (pixel values), the pixel values of the interpolation area (inside the area) are close to those of the background image, and visual quality deterioration is reduced.

As a specific interpolation method, a document “MPEG
4 Video Verification Mode
l Version 2.0 ”(ISO / IEC JT
C1 / SC29 n1260, 1996). In addition, an interpolation method using an average value of the pixel values of the background area, a predetermined constant value, or an interpolation image creation method that reproduces texture information of the background area using fractal may be used. .

Next, a second embodiment of the present invention will be described. This is for solving the above-mentioned second problem, and FIG. 2 is a block diagram showing a configuration of an image superimposing unit included in the apparatus of the present embodiment.

Note that the first area extraction unit 10 shown in FIG.
1, second region extraction unit 102, controller 103, switch 104, interpolation image creation unit 105, weighted average unit 10
6 is the same as that shown in FIG. 1, and a detailed description thereof will be omitted.

The third region extracting section 207 in FIG. 2 extracts a region where the first region and the second region of the lower layer intersect (ie, an overlapping region of the component region of the lower layer appearing as the background). In the example of FIG. 13A, a white area surrounded by a dotted line and a broken line corresponds to this.

The pixel value interpolation section 208 in FIG. 2 performs interpolation of the area extracted by the third area extraction section 207. That is, the pixel value interpolation unit 208 compares the pixel value in the area (overlap area) with the information adjacent to the peripheral part (ie, the lower layer appearing as the background) for the composite pixel created by the controller 103 and the switch 104. (Pixel values around the overlapping region of the component regions).

As a result, image information for predictive encoding / decoding of the upper layer is generated. This interpolation processing is the same as the processing of the interpolation unit 1804 shown in FIG.

Next, a third embodiment of the present invention will be described. The apparatus according to the present embodiment includes the first and second
This is to solve the problem described above, and is configured by incorporating the adaptive background interpolation determination device described in the first embodiment into the second embodiment.

FIG. 3 is a block diagram showing the configuration of an image superimposing unit provided in the device according to the third embodiment. The first area extraction unit 101, the second area extraction unit 102, the controller 103, the switch 104, the interpolation image creation unit 105, the background interpolation determination unit 108, the weighted average unit 106, and the switch 11 of FIG.
0 operates in the same manner as shown in FIG. 1, and similarly, the third region extracting unit 207 and the pixel value interpolating unit 208 operate in the same manner as shown in FIG. Is omitted.

As described above, the apparatus of this embodiment has the configuration of the apparatus of the above-described first and second embodiments in combination, so that the motion is small and the useless shape information is not obtained when the effect of interpolation is not seen. Not only can encoding be avoided, but also a reduction in image quality caused by a reciprocating (turning back) motion of the upper layer component area can be reduced.

Next, a fourth embodiment of the present invention will be described. This is for solving the first, second and fourth problems described above. FIG. 4 is a block diagram showing the configuration of an image superimposing unit provided in the apparatus of the present embodiment.

Here, the first pixel value interpolation unit 401 shown in FIG.
Interpolates the first component region in the first decoded image of the lower layer in the same manner as the pixel value interpolation unit 208 in FIG. Similarly, the second pixel value interpolation unit 402 in FIG. 4 performs interpolation of the second component area in the second decoded image of the lower layer. A specific description of the operation has already been given in the description of the pixel value interpolation unit 208 in FIG.

The first interpolated image creating unit 403 in FIG. 4 interpolates the output of the first pixel value interpolating unit 401 and the output of the second pixel value interpolating unit 402 in accordance with the above equation (1). On the other hand, FIG.
The second interpolated image creating unit 404 converts the first decoded image and the second decoded image of the lower layer into the first interpolated image creating unit 4
As in 03, interpolation is performed according to equation (1).

In each case, the operation is exactly the same as that of the interpolated image creating unit 105 in FIG. 1, and the description is omitted here.
The weighted averaging unit 106 and the switch 108 are the same as those shown in FIG.

The background interpolation determining section 407 in FIG. 4 is a section for determining whether or not to perform the combining process, similarly to the background interpolation creating section 107 in FIG. 1. Based on this determination, the background given to the weighted average section 106 is determined. An image (a lower layer to be superimposed on an upper layer) is determined.

That is, when the background interpolation determination unit 407 determines that the component area of the lower layer appearing as the background is larger than the predetermined threshold, the weighted average unit 106 determines the pixel value around the component area of the lower layer. Is input from the first interpolation image creation unit 403, and using this, the pixel values inside the component area are interpolated to generate image information.

When the background interpolation determining unit 407 determines that the component area appearing as the background is smaller than the predetermined threshold, the weighted averaging unit 106 generates an image obtained by performing a weighted average of the lower layer. , The second interpolation image creation unit 4
The image information is generated by interpolating the pixel values inside the component area using the input from the input unit 04.

In the present embodiment, the synthesizing process in the conventional example is simplified, and the scale of the hardware can be reduced without causing a large decrease in image quality.

Although the second interpolated image creating unit 404 shown in FIG. 4 of the present embodiment performs interpolation according to equation (1), the second interpolated image creating unit 404 adds time to the current upper layer frame according to equation (5). A configuration may be adopted in which interpolation is performed using pixels of a lower layer frame that is close to the target.

That is, for example, when the temporally lower layer frame is temporally close, the background interpolation determining unit 407 determines whether or not to perform background interpolation based on the area represented by the equation (6). I do. In addition, the first interpolation image creation unit 4 shown in FIG.
03 outputs the image created by the first pixel value interpolation unit 401 as it is.

Next, a fifth embodiment of the present invention will be described. The apparatus according to the present embodiment is for solving the above-described first problem. When the difference between the positions and shapes of the first component area and the second component area in the lower layer is small, the second apparatus is used. By replacing the component area with the first component area, the code amount required for the second component area information is reduced.

The image superimposing unit provided in the apparatus of the present embodiment
In the configuration shown in FIGS. 1 to 4, the input unit for the first area information and the second area information of the lower layer is further provided with the components shown in FIG.

Here, the comparison section 501 in FIG. 5 is a section for judging a difference between two pieces of area information of the lower layer. If the component image of the lower layer does not move much and the change of the area information representing the component image is small, instead of using the second area information of the lower layer, the switch 502 of FIG. 1 is output, and the area information that needs to be encoded is reduced by one.

When the component area of the lower layer moves largely, the switch is connected to the lower side, and each area information is output. As a judgment material of the change of the area information,
For example, the area of the shaded portion shown in FIG. 9 may be used.

Next, a sixth embodiment of the present invention will be described. The device according to the present embodiment is for solving the above-described third problem, and FIG. 7 is a block diagram illustrating the configuration of an image superimposing unit included in the device according to the present embodiment.

As shown in the figure, the image superimposing unit provided in the present apparatus is different from the configuration of the first embodiment shown in FIG. 1 in that a presence determining unit 709 and a third interpolation image creating unit 71
0, and switches 711 and 712.

The first area extracting section 101, second area extracting section 102, weighted averaging section 106, switch 1 shown in FIG.
The operation of 08 is the same as that shown in FIG. 1, and the description is omitted here. Further, the controller 703, the switch 704, and the interpolation image creation unit 705 correspond to the controller 103, the switch 104, and the interpolation image creation unit 105 in FIG. 1, respectively.

First, when the background interpolation judging section 707 judges that the component area of the lower layer appearing as the background is larger than a predetermined threshold value, the switch 108 is connected to the left side (output of the switch 704).

Then, the existence determining unit 709 of FIG. 7 determines whether the first decoded image and the second decoded image of the lower layer exist, that is, the number of lower layer frames required for background interpolation is satisfied. It is determined whether or not it has been performed.

Here, when the existence determining unit 709 determines that one of the decoded images has not been input, the controller 7
03, the switch 704 is connected to the leftmost position (the output of the third interpolation image creation unit 710).

At the same time, the switch 711 and the switch 71
2 are connected such that the existing decoded image and the corresponding area information are input to the third interpolation image creation unit 710. For example, if there is no second decoded image that is a decoded image that is later in time, the switch is connected so that the first decoded image and the first area information are input.

Next, the third interpolated image creating section 710 shown in FIG.
Performs an interpolation process on the component region inside the decoded image by using the pixel values around the component region by the same operation as the pixel value interpolation unit 208 in FIG. If the presence determination unit 709 determines that there is no input, the switch 704 is connected to the leftmost position. In this case, the output of the third interpolation image generation unit 710 is Used for superimposition.

In some cases, the interpolated image creating unit 705 and the background interpolation determining unit 707 shown in FIG. In this case, the interpolation image determination unit 707 determines whether to perform background interpolation using the size of the input lower layer component area that cannot be covered by the upper layer component area. Also, the interpolation image creation unit 705 does not perform interpolation,
The decoded image is output as it is.

In the first to sixth embodiments described above, the determination as to whether or not to perform background interpolation is made for each upper layer frame. However, the determination is made between two consecutive lower layer frames. When there are a plurality of upper layer frames, background interpolation may be performed as follows.

That is, it is once determined whether or not to perform background interpolation on each of the plurality of upper layer frames (upper layer frames in which no frame corresponding to the lower layer exists). If it indicates that background interpolation is not to be performed, background interpolation is not performed for all of the plurality of upper layer frames.

In this case, the upper layer frame has two
It is superimposed on an interpolated image of one lower layer frame or on a lower layer frame that is temporally closer.

When it is determined that background interpolation is performed on at least one upper layer frame (when the component area of the lower layer appearing as the background is larger than a predetermined threshold value for one of the plurality of upper layers) ), A lower layer frame synthesized by background interpolation is superimposed on all of the plurality of upper layer frames.

Specifically, for all of the plurality of upper layers, image information is generated by combining a frame obtained by weighted averaging of lower layers and a frame of the lower layer.

In this case, of the plurality of upper layer frames, for example, background interpolation is performed only on the temporally first frame to synthesize a lower layer frame, and for the remaining upper layer frames, The lower layer frame synthesized with the upper layer frame may be used as it is.

In the apparatuses according to the first to sixth embodiments, when the distortion of the image shown by the halftone dot in FIG. 14C or FIG. 16 is large, the distortion is removed by background interpolation. However, when the distortion of the image is small, the background interpolation is not performed, and the distortion of the image slightly exists.

In this case, the distortion of the image is not visually noticeable, but it is possible to prevent this distortion from occurring visually as follows.

That is, when encoding of the upper layer is performed together with the component area of the upper layer, FIG.
The component area of the lower layer indicated by the halftone dot No. 6 is also encoded.
For this purpose, the component area of the upper layer is changed (expanded / expanded) so as to include both the hatched portion and the halftone dot portion in FIGS.

FIG. 17 is a block diagram of an area conversion unit for performing the process of changing the part area. This region conversion unit expands the component region of the upper layer using the component region of the lower layer and generates this as the component region of the image information, whereby the upper layer encoding unit 110 shown in FIG.
3 is converted.

The operation of each component of the area conversion unit shown in FIG. 17 will now be described. In the figure, a switch 1701 separates region information into region information of an upper layer and region information of a lower layer. Memory 1702 in FIG.
Temporarily stores the area information of the lower layer. The area integrating unit 1703 integrates part of the lower layer area information with the upper layer area information to create new area information.

More specifically, for example, when creating an interpolated image in accordance with equation (1), the interpolated image creating unit 105 of FIG. 1 integrates the halftone dot portion of FIG. 14 (c) into the area information of the upper layer. Then, new area information is created. When the interpolated image creating unit 105 is configured to create an interpolated image by selecting a lower layer that is close in time according to Equation (5), the halftone dot part in FIG. Integrated into the information.

Next, the switch 1704 in FIG. 17 is connected to the upper side (upper layer area information) when background interpolation is performed, and to the lower side (output of the area integration unit 1703) when background interpolation is not performed. The switch 1705 is connected to the upper side when the upper layer area information is being processed, and is connected to the lower side when the lower layer area information is being processed, in synchronization with the switch 1701.

As described above, when background interpolation is not performed, image distortion can be prevented from occurring by changing and expanding / expanding the area information of the upper layer.

As is clear from the above description, according to the embodiments of the present invention, the following effects can be obtained.

(1) If the component areas in the lower layer and upper layer images do not move much and the effect is not visually obtained even if background interpolation is performed, background interpolation is not performed. When the area moves greatly, background interpolation is performed, whereby the shape information for background interpolation can be reduced, and a higher image quality can be achieved.

(2) When the component images in the lower layer and upper layer images perform a reciprocating motion, a turning motion, or a turning motion instead of moving in one direction, the component image regions of the lower layer overlap. On the other hand, by performing interpolation using the surrounding pixel values, it is possible to reduce a visual deterioration in image quality.

(3) When there is no lower layer temporally preceding or succeeding the image of the upper layer to be coded, only the existing lower layer is used, and the component image area is determined by using the surrounding pixel values. By performing the interpolation, it is possible to reduce an apparent decrease in image quality.

(4) The size of the hardware can be reduced by simplifying the interpolation using the pixel values around the component image area without switching the screen used for the interpolation processing of the component image area for each area. Can be.

(5) When a plurality of upper layer frames exist between two consecutive lower layer frames, when performing background interpolation, only the first upper layer frame of the plurality of upper layer frames is used. By performing the background interpolation, it is possible to reduce the processing amount of the background interpolation and the code amount of the component area information of the lower layer required for the background interpolation.

(6) When background interpolation is not performed, when coding the upper layer, the region to be interpolated by the background interpolation is coded together with the component region of the upper layer so that background interpolation is not performed. The resulting image distortion can be prevented from visually occurring.

[0125]

Since the moving picture coding apparatus and the moving picture decoding apparatus of the present invention have the above-described configuration, there is no case where a lower layer temporally preceding or lower than an image of an upper layer does not exist. Also, by using only the existing lower layer and interpolating the component image area using surrounding pixel values, it is possible to reduce the apparent deterioration in image quality.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of an image superimposing unit included in a video encoding device and a video decoding device according to a first embodiment of the present invention.

FIG. 2 is a block diagram illustrating a configuration of an image superimposing unit included in a video encoding device and a video decoding device according to a second embodiment of the present invention.

FIG. 3 is a block diagram illustrating a configuration of an image superimposing unit included in a video encoding device and a video decoding device according to a third embodiment of the present invention.

FIG. 4 is a block diagram illustrating a configuration of an image superimposing unit included in a video encoding device and a video decoding device according to a fourth embodiment of the present invention.

FIG. 5 is a block diagram illustrating a configuration of a region information conversion unit included in a video encoding device and a video decoding device according to a fifth embodiment of the present invention.

FIG. 6 is a block diagram illustrating a configuration of a background interpolation determining unit included in the image superimposing unit of the device according to the first embodiment of the present invention.

FIG. 7 is a block diagram illustrating a configuration of an image superimposing unit included in an apparatus according to a sixth embodiment of the present invention.

FIG. 8 is a diagram for explaining a problem of a conventional device.

FIG. 9 is a diagram for explaining an operation of the device according to the fifth embodiment of the present invention.

FIG. 10 is a diagram for explaining a problem of a conventional device.

FIG. 11 is a block diagram illustrating a configuration of a video encoding device and a video decoding device.

FIG. 12 is a block diagram illustrating a configuration of an image superimposing unit included in a conventional device.

FIG. 13 is a diagram for explaining an operation of an image superimposing unit provided in a conventional device.

FIG. 14 is a diagram for explaining a problem of an image superimposing unit provided in a conventional device.

FIG. 15 is a diagram for explaining the concept of frame synthesis in the video encoding device and the video decoding device.

FIG. 16 is a diagram for explaining an operation of an interpolation image creation unit provided in the image superposition unit of the device according to the first embodiment of the present invention.

FIG. 17 is a block diagram illustrating a configuration of an area information conversion unit included in the device according to the embodiment of the present invention.

FIG. 18 is a block diagram illustrating another configuration of the image superimposing unit included in the apparatus according to the embodiment of the present invention.

[Explanation of symbols]

101 first region extraction unit 102 second region extraction unit 103, 703, 1802 controller 104, 108, 502, 704, 711, 712 switch 105, 705 interpolation image creation unit 106 weighted average unit 107, 407, 707 background interpolation Judgment unit 207 Third region extraction unit 208 Pixel value interpolation unit 305, 403 First interpolation image creation unit 401 First pixel interpolation unit 402 Second pixel interpolation unit 404 Second interpolation image creation unit 501 Area comparison unit 601 Area measurement unit 602 Comparison determination unit 709 Presence determination unit 710 Third interpolation image creation unit 1702 Memory 1703 Area integration unit 1801 Selection unit 1804 Interpolation unit

──────────────────────────────────────────────────続 き Continuation of front page (72) Inventor Hiroshi Kusao 22-22 Nagaikecho, Abeno-ku, Osaka-shi, Osaka Inside Sharp Corporation (56) References JP-A-7-38899 (JP, A) JP-A-60- 206287 (JP, A) JP-A-60-128791 (JP, A) Eito, Bun, Sumino, "Image coding using hierarchical representation and multiple templates", IEICE Technical Report, March 1995 , Vol. 94, no. 549, p. 99- 106 Sumino, Tsuda, Bun, Eito, "Image Coding Using Transparency Information in Region Representation", Information Processing Society of Japan Research Report, Audiovisual Complex Information Processing 95-AVM-9, July 1995, Vol. . 95, No. 64, p. 1-8 (58) Fields surveyed (Int. Cl. ⁷ , DB name) H04N ^7/ 24-7/68 INSPEC (DIALOG) JICST file (JOIS)

Claims (5)

(57) [Claims] 1. A means for separating one moving image sequence into a lower layer having a lower frame rate and an upper layer having a higher frame rate; and a lower layer code for encoding an entire image of the moving image sequence in the lower layer. Encoding means; an upper layer encoding means for encoding a partial area of the image of the moving image sequence as a component image in the upper layer; and encoding area information indicating a partial area shape of the image of the moving image sequence. time and region information encoding means, wherein when the lower layer frame to the higher temporally corresponding to the layer frame does not exist, in said upper layer frame for reduction
Between to corresponding lower layer frame by using the lower layer frames existing temporally before or after, and a superposing means for generating a background image, superimposes the part images of the higher layer frame on the background image A moving image encoding apparatus that predictively encodes the upper layer using an image created by the superimposing means, wherein the superimposing means is configured such that the lower layer frame is temporally preceding an upper layer frame. In the case where the moving image sequence exists only in the lower layer frame temporally preceding the upper layer frame,
A moving image encoding apparatus, wherein the background image is generated by interpolating the inside of a corresponding component image area using surrounding pixel values. 2. A means for separating one moving image sequence into a lower layer having a lower frame rate and an upper layer having a higher frame rate; and a lower layer code for encoding an entire image of the moving image sequence in the lower layer. Encoding means; upper layer encoding means for encoding a partial region of the image of the moving image sequence as a component image in the upper layer; encoding region information indicating a partial region shape of the image of the moving image sequence time and region information encoding means, wherein when the lower layer frame to the higher temporally corresponding to the layer frame does not exist, in said upper layer frame for reduction
Between to corresponding lower layer frame by using the lower layer frames existing temporally before or after, and a superposing means for generating a background image, superimposes the part images of the higher layer frame on the background image A moving image encoding apparatus that predictively encodes the upper layer using an image created by the superimposing unit, wherein the superimposing unit is configured such that the lower layer frame is temporally behind the upper layer frame. In the case where there is only an image, a part of the image of the moving image sequence in the lower layer frame that is temporally subsequent to the upper layer frame is
A moving image encoding apparatus, wherein the background image is generated by interpolating the inside of a corresponding component image area using surrounding pixel values. 3. The moving picture coding apparatus according to claim 1, wherein the component image area of the lower layer frame that cannot be covered by the component image of the upper layer frame is smaller than a predetermined threshold value. If smaller, the component image area of the upper layer frame is replaced with the component image of the lower layer frame.
A moving picture coding apparatus characterized in that the moving picture coding apparatus is extended to include a region . 4. A lower layer decoding means for decoding encoded data of a lower layer obtained by encoding an entire image of a moving image sequence at a low frame rate, and a part image of an image of the moving image sequence at a high frame rate. encoded and upper layer decoding means for decoding the coded data of the upper layer, the area information for decoding the encoded data of the coded area information on the area information indicating the partial area shape of the image of the moving image sequence as a If the decoding means, not the lower layer frame temporally corresponding to the higher layer frame is present, a time to said upper layer frame
Between to corresponding lower layer frame by using the lower layer frames existing temporally before or after, and a superposing means for generating a background image, superimposes the part images of the higher layer frame on the background image A moving image decoding apparatus that displays an image created by the superimposing means on a display, wherein the superimposing means includes a step of, when the lower layer frame exists only temporally before an upper layer frame, A partial region of an image of the moving image sequence in a lower layer frame existing temporally before a layer frame is
A moving image decoding apparatus, wherein the background image is generated by interpolating the inside of a corresponding part image area using pixel values around the corresponding part image area. 5. A lower layer decoding means for decoding encoded data of a lower layer obtained by encoding an entire image of a moving image sequence at a low frame rate, and a partial image of a moving image sequence at a high frame rate. encoded and upper layer decoding means for decoding the coded data of the upper layer, the area information for decoding the encoded data of the coded area information on the area information indicating the partial area shape of the image of the moving image sequence as a If the decoding means, not the lower layer frame temporally corresponding to the higher layer frame is present, a time to said upper layer frame
Between to corresponding lower layer frame by using the lower layer frames existing temporally before or after, and a superposing means for generating a background image, superimposed on the component image of the upper layer frame in the background image A moving image decoding apparatus for displaying an image created by the superimposing means on a display, wherein the superimposing means comprises: the upper layer when the lower layer frame exists only temporally after the upper layer frame. A part of an image of the moving image sequence in a lower layer frame existing temporally after the frame is
A moving image decoding apparatus, wherein the background image is generated by interpolating the inside of a corresponding part image area using pixel values around the corresponding part image area.