JPH08140096A - Method and device for coding image signal - Google Patents

Abstract

PURPOSE: To efficiently perform coding by dividing picture element blocks according to the presence or absence of a picture element to be coded and eliminating the coding of the picture element block where the picture element to be coded does not exist. CONSTITUTION: A blocking means 2 where a picture element value signal 1 is defined as an input signal and a picture element block 3 is defined as an output signal and an effective block decision means 5 where a picture element location signal 4 to be coded is defined as the input signal and a control signal 6 is defined as the output signal are connected with a selection means 7 where the picture element block 3 and the control signal 6 are defined as input signals and a picture element block 8 to be coded is defined as the output signal. The selection means 7 is connected with a coding means 9 where the picture element block 8 to be coded is defined as the input signal and a coding signal 10 is defined as the output signal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is a video signal coding method applicable to various applications for coding general video scenes.

[0002]

2. Description of the Related Art Conventionally, encoding of pixel value information for a video scene is performed for a single layer. That is, the pixel value information of all the contents of one scene of the video is completed on a single layer, and the encoding is performed for each pixel value information of the single layer.

When the pixel value information completed in the single layer is coded, the need for efficient coding is increasing more and more, and it is necessary to carry out with a high compression rate. Under such circumstances, currently JPEG is used for still images and MPEG1, MPEG2, I for moving images.
ITU-T Recommendation H.264. A method based on an international standard such as 261 is used.

[0004]

However, in the conventional means for encoding the pixel value information that is completed in a single layer, even if a pixel that does not need to be encoded exists in that single layer, Encoding must take into account pixel values. Therefore, there is a problem that the amount of coding increases and the processing speed becomes slow.

The present invention has been made in view of the above problems of the prior art, and an object of the present invention is to efficiently encode an image signal.

[0006]

According to a first aspect of the present invention, a code obtained by determining whether or not an image signal is a pixel region to be encoded by the transmission state of the pixel value and encoding the determination result. The image signal encoding method is characterized in that a pixel region to be encoded is encoded by a predetermined encoding method based on a pixel position signal to be encoded.

[0007]

With respect to the image signal, depending on the transmission state of the pixel value,
It is determined whether the pixel region is to be encoded, and based on the pixel position information to be encoded obtained by encoding the determination information, only the pixel region to be encoded of the image signal is encoded by a predetermined encoding method. To convert.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to block diagrams showing its embodiments.

FIG. 1 is a block diagram of an embodiment of an image signal coding apparatus according to the present invention of claim 2. That is, as shown in FIG. 1, the pixel value signal 1 is used as an input signal,
Blocking means 2 that uses the pixel block 3 as an output signal;
The effective block determination means 5 having the pixel position signal 4 to be encoded as an input signal and the control signal 6 as an output signal receives the pixel block 3 and the control signal 6 as an input signal, and determines the pixel block 8 to be encoded. Selection means 7 for output signal
It is connected to the. The selecting means 7 is connected to the encoding means 9 which receives the pixel block 8 to be encoded as an input signal and the encoded signal 10 as an output signal.

Next, the operation of the above embodiment will be described.

Pixel value signal 1 containing image pixel value information
However, when the image is input to the blocking means 2, the image is 1
The pixel block is divided into 6 × 16 pixels and is output as a pixel block 3 from the blocking unit 2.

Here, the pixel position signal 4 to be encoded is
It is a signal coded by determining whether or not to code from the transparency of the pixel value signal of the image. (Transparency 0%
Is a state where there is an opaque object and the background cannot be seen,
When the transparency is 100%, the background is visible without any object. The intermediate level value appears when there is a translucent object such as glass and at the boundary between the objects. ) When the pixel position signal 4 to be encoded is input to the effective block determining means 5, it is determined whether or not the block synchronized with the pixel block 3 includes a pixel value to be encoded. A signal based on this is output as a control signal 6 from the valid block determining means 5. That is, when the control signal 6 and the pixel block 3 are input to the selection means 7, when the effective block determination means 5 determines that the pixel block 3 includes a pixel value to be encoded, The pixel block 3 is output from the selecting means 7 as a pixel block 8 to be encoded. When the valid block determining means 5 determines that the pixel block 3 does not include the pixel value to be encoded, the selecting means 7 does not output the pixel block 8 to be encoded. When the pixel block 8 to be encoded outputted from the selecting means 7 is inputted to the encoding means 9, multi-level encoding using DCT is performed and an encoded signal 10 is output.

Here, FIG. 2 is a diagram showing pixel block formation in this embodiment. The black filled figure in the diagram on the left side of FIG. 2 represents a pixel determined to be a pixel to be encoded according to the transparency of the pixel value, and the block filled with the stitch in the diagram on the right side of FIG. , A pixel block to be encoded divided based on the information of the pixel to be encoded.

That is, in this embodiment, not only the pixel block including the pixel to be encoded but also the pixel block not including the pixel to be encoded can be uniquely specified from the pixel position signal to be encoded. By omitting the encoding of those pixel blocks, the image signal encoding device can improve the encoding efficiency.

The multi-level coding in the coding means 9 is D
Although CT is used, the present invention is not limited to this, and multi-level coding that combines orthogonal transformation and entropy coding may be used. In short, any multi-level encoding method that can efficiently perform multi-level encoding will do.

Further, although the pixel block has a configuration of 16 × 16 pixels, the configuration is not necessarily limited to this, and a configuration of 32 × 32 pixels may be used. In short, any pixel configuration that can improve the encoding efficiency may be used.

Although the pixel value transparency is used as the means for determining whether or not the pixel is to be encoded, the invention is not limited to this, and the brightness with the pixel value transparency information superimposed thereon is also used. Good. In short, it suffices if the information on the transmission state of the pixel value is included.

FIG. 3 is a block diagram of one embodiment according to the image signal coding apparatus of the present invention of claim 3. That is, a large block forming means 2 that uses the pixel value signal 1 as an input signal and a large pixel block 3 as an output signal, and a small block forming means that uses the pixel value signal 1 as an input signal and a small pixel block 5 as an output signal. 4, a pixel position signal 6 to be coded as an input signal and a control block 8 as an output signal, an effective large block determining means 7, a pixel position signal 6 to be coded as an input signal, and a control signal 10 as an output signal. And the effective small block determining means 9 that selects the large pixel block, the small pixel block, the control signal 8 and the control signal 10 as input signals, and the pixel block 12 to be encoded as an output signal 11 It is connected to the. The selection means 1
1 is the pixel block to be encoded and the control signal 8
And the control signal 10 as input signals, and the encoded signal 14
Is connected to the encoding means 13 whose output signal is.

Next, the operation of the above embodiment will be described.

Pixel value signal 1 containing image pixel value information
However, when the image is input to the large block forming means 2, the image is 1
It is divided into large blocks of 6 × 16 pixels and output as a large pixel block 3. Also, the pixel value signal 1
However, when the image is input to the small block forming means 4, the image is converted into 8
It is divided into small blocks of x8 pixels and output as a small pixel block 5.

Here, the pixel position signal 6 to be encoded is
It is a signal coded by determining whether or not to code from the transparency of the pixel value signal of the image.

When the pixel position signal 6 to be encoded is input to the effective large block determination means 7, it is determined whether or not the block synchronized with the large pixel block includes a pixel value to be encoded, A signal based on the determination is output from the effective large block determination means 7 as a control signal 8. Also, the pixel position signal 6 to be encoded
Is input to the effective small block determination means 9, it is determined whether or not the block synchronized with the small pixel block 5 includes a pixel value to be encoded, and a signal based on the determination is effective. The small block determination means 9 outputs the control signal 10.

When the large pixel block 3, the small pixel block 5, the control signal 8 and the control signal 10 are input to the selection means 11, the large pixel block 3 and the small pixel block 7 are The control signal 8 and the control signal 1
A pixel block 12 to be encoded, controlled by
Is output. That is, when it is determined that all of the four small pixel blocks included in the large pixel block 3 include pixels to be encoded, the large pixel block 3 causes the selection unit 11 to select pixels to be encoded. It is output as block 12. Further, in cases other than the above, at least one or more small pixel blocks among the four small pixel blocks included in the large pixel block 3,
When it is determined that the pixel to be encoded is included, only the small pixel block 5 that is determined to include the pixel to be encoded is sequentially output from the selecting unit 11 as the pixel block 12 to be encoded.

When the pixel block 12 to be encoded, the control signal 8 and the control signal 10 are input to the encoding means 13, the pixel block 12 to be encoded is
The encoded signal 14 is output under the control of the control signal 8 and the control signal 10. That is, when it is determined by the control signal 8 and the control signal 10 that all of the four small pixel blocks included in the large pixel block 3 include the pixel to be encoded, the pixel to be encoded The block 12 is multivalued encoded by DCT corresponding to a large pixel block, and the encoding means 1 is used.
The coded signal 14 is output from 3. Further, in other cases than the above, at least one or more small pixel blocks among the four small pixel blocks included in the large pixel block 3 are encoded by the control signal 8 and the control signal 10. If it is determined that the pixel block 12 to be encoded includes the pixel value to be encoded, the pixel block 12 to be encoded is subjected to multi-level encoding by DCT corresponding to the small pixel block, and the encoded signal 14 is output from the encoding unit 13. To be done. In other cases, the coded signal 14 is not output.

Here, FIG. 4 is a diagram showing a large pixel block and a small pixel block in this embodiment. The large pixel block in the diagram on the left side of FIG. 4 is divided into the small pixel blocks in the diagram on the right side, thereby encoding three small pixel blocks without filling of these four small pixel blocks. It turns out that can be omitted.

That is, in the present embodiment, the screen is divided into large pixel blocks having the same area, and the large pixel blocks are further divided into smaller small pixel blocks, so that it is necessary to perform encoding included in the large pixel blocks. The image signal encoding device can improve the encoding efficiency by omitting the encoding of the small pixel blocks that are not present.

The multi-level coding in the coding means 13 is as follows.
Although the DCT is used, the present invention is not limited to this, and multilevel coding that combines orthogonal transformation and entropy coding may be used. In short, any multi-level encoding method that can efficiently perform multi-level encoding will do.

Although the large pixel block has a configuration of 16 × 16 pixels, the configuration is not limited to this, and a configuration of 32 × 32 pixels may be used. The small pixel block has a configuration of 4 × 4 pixels in response to this, but the configuration is not limited to this, and a configuration of 8 × 8 pixels may be used. In short, any pixel configuration that can improve the encoding efficiency may be used.

Although the pixel value transparency is used as the means for determining whether or not the pixel is to be encoded, the invention is not necessarily limited to this, and even if the brightness of the pixel value transparency information is superimposed. Good. In short, it suffices if the information on the transmission state of the pixel value is included.

FIG. 5 is a block diagram of one embodiment according to the image signal coding apparatus of the present invention of claim 4. That is, the pixel value signal 1 is used as an input signal, the pixel slice unit 3 is used as an output signal, and the pixel position signal 4 to be encoded is used as an input signal, and the control signal 6 is used.
Is connected to block forming means 7 which receives the pixel block slice 3 and the control signal 6 as input signals and outputs a pixel block 8 to be encoded as an output signal. . The blocking means 7 is connected to a coding means 9 which receives the pixel block 8 to be coded as an input signal and a coded signal 10 as an output signal.

Next, the operation of the above embodiment will be described.

Pixel value signal 1 containing image pixel value information
However, when the image is input to the block slicing means 2, the image is divided into pixel block slices obtained by slicing with a height of 16 pixels, and output as a pixel block slice 3.

Here, the pixel position signal 4 to be encoded is
It is a signal coded by determining whether or not to code from the transparency of the pixel value signal of the image.

When the pixel position signal 4 to be encoded is input to the block formation start position means 5, it is a signal corresponding to the start position of pixel block formation consisting of 16 × 16 pixels with respect to the pixel block slice 3. The control signal 6 is
It is output from the block formation start position determination means 5. When the pixel block slice 3 and the control signal 6 are input to the blocking unit 7, the pixel block slice 3 is pixel-blocked with 16 × 16 pixels. That is, when it is determined by the control signal 8 that the pixel block slice 3 includes a pixel to be encoded, the pixel to be encoded is 16 × 16 pixels from the pixel position where the pixel is first detected. Pixel blocking is performed. Then, among the pixel blocks obtained by dividing the pixel block slice, only the pixel blocks that are determined to include the pixel value to be encoded are sequentially pixel blocks 8 to be encoded from the blocking means 7.
Is output as The pixel block 8 to be encoded
Is input to the encoding means 9, multi-level encoding using DCT is performed, and the encoded signal 10 is output.

Here, FIG. 6 is a diagram showing pixel block formation in this embodiment. As shown in FIG. 2, if the pixel block is divided into blocks according to the first embodiment of the present invention of claim 2, the pixel block to be encoded is an 11 pixel block as shown in the right column of FIG. is there. However, FIG.
As shown in FIG. 5, if the pixel block is divided into blocks by the present embodiment, the pixel block to be encoded becomes 9 pixels as shown in the lower stage of FIG.
It can be seen from the pixel value layer encoding method according to the embodiment that the number of pixel blocks to be encoded can be omitted by two pixel blocks.

That is, in the present embodiment, the pixel block is formed such that the start position of the pixel block to be encoded is located at the pixel position to be encoded that is first detected in the horizontal direction. Compared with the embodiment described above, the number of pixel blocks to be encoded may be reduced in some cases, and in this case, the image signal encoding device can further improve the encoding efficiency.

Note that the multi-level coding in the coding means 9 is D
Although CT is used, the present invention is not limited to this, and multi-level coding that combines orthogonal transformation and entropy coding may be used. In short, any multi-level encoding method that can efficiently perform multi-level encoding will do.

The height of the pixel block slice is set to 16
Although pixels are used, the number of pixels is not limited to 32 and may be 32 pixels. Then, in correspondence with this, the pixel block is 16 ×
Although the configuration of 16 pixels is adopted, the invention is not limited to this, but 32
A configuration of × 32 pixels may be used. In short, any pixel configuration that can improve the encoding efficiency may be used.

Although the pixel value transparency is used as the means for determining whether or not the pixel is to be coded, the invention is not limited to this, and the brightness with the pixel value transparency information superimposed thereon is also used. Good. In short, it suffices if the information on the transmission state of the pixel value is included.

FIG. 7 is a block diagram of one embodiment according to the image signal coding apparatus of the present invention of claim 5. That is, the horizontal effective pixel range detecting means 5 using the pixel position signal 4 to be encoded as an input signal and the control signal 6 as an output signal.
And using the pixel position signal 4 to be encoded as an input signal,
A vertical effective pixel range detecting means 7 having a control signal 8 as an output signal is connected to a selecting means 2 having a pixel value signal 1 as an input signal and a single pixel block 3 to be encoded as an output signal. The connecting means 2 is connected to an encoding means 9 which receives the single pixel block 3 to be encoded as an input signal and an encoded signal 10 as an output signal.

Next, the operation of the above embodiment will be described.

The pixel position signal 4 to be coded is a signal coded by judging whether or not to code from the transparency of the pixel value signal of the image.

When the pixel position signal 4 to be coded is inputted to the horizontal effective pixel range detecting means 5, the pixel position signal 4 to be coded which is first detected in the horizontal direction from the pixel position signal 4 to be coded. A control signal 6 based on the last detected pixel position to be encoded is output from the horizontal effective pixel range detecting means 5. Further, when the pixel position signal 4 to be encoded is input to the vertical effective pixel range detection means 7, from the pixel position signal 4 to be encoded,
The pixel position to be encoded first detected in the vertical direction,
A control signal 8 based on the last detected pixel position to be encoded is output from the vertical effective pixel range detecting means 7.

When the pixel value signal 1 including the pixel value information of the image, the control signal 6 and the control signal 8 are input to the selecting means 2, the control signal 6 and the control signal 8 cause With respect to the pixel value signal 1, the smallest single pixel block including the pixel value to be encoded is formed, and the selection unit 2 outputs the single pixel block 3 to be encoded.
Even if the single pixel block 3 to be encoded is input to the encoding means 9 which performs multi-level encoding by Wavelet encoding which cannot encode a plurality of blocks, since it is a single pixel block, a large number is obtained by the encoding. Value coding can be performed, and the coded signal 10 is output from the coding means 9.

Here, FIG. 8 is a diagram showing a single block of this embodiment. As shown in the diagram on the right side of FIG. 8, it can be seen that the coding of the shaded area can be omitted by forming the smallest single pixel block including the pixel value to be coded. .

That is, according to the present embodiment, even when a coding method in which a pixel value signal composed of a plurality of blocks cannot be coded is used for coding a pixel value signal, the smallest single value including the pixel value to be coded is used. This is an image signal encoding device that enables encoding by configuring a pixel block.

The multi-level coding in the coding means 9 is W
Avelet encoding is used, but not limited to this.
Multi-level coding that combines orthogonal transformation and entropy coding may be used. In short, any multi-level encoding method that can efficiently perform multi-level encoding will do.

Further, the pixel value transparency is used as the means for determining whether or not the pixel is to be coded, but the invention is not limited to this, and the brightness with the pixel value transparency information superimposed thereon is also used. Good. In short, it suffices if the information on the transmission state of the pixel value is included.

FIG. 9 is a block diagram of one embodiment according to the image signal coding apparatus of the present invention of claim 6. That is, the block forming means 2 having the pixel value signal 1 as the input signal and the pixel block 3 as the output signal, and the effective block determining means 5 having the pixel position signal 4 to be encoded as the input signal and the control signal 6 as the output signal. Are connected to the selecting means 7 which receives the pixel block 3 and the control signal 6 as input signals and outputs the pixel block 8 to be encoded as output signals.
The selection means 7 and the pixel value generation means 9 having the pixel position signal 4 to be encoded and the pixel block 8 to be encoded as input signals and the high frequency component reduction signal 10 as an output signal should be encoded. Blocking means 1 that uses the pixel position signal 4, the pixel block to be encoded, and the high-frequency component reduction signal 10 as input signals, and outputs the pixel block 12 to be encoded that includes the high-frequency component reduction signal as an output signal.
Connected to 1. The blocking means 11 is connected to a coding means 13 which uses a pixel block 12 including the high frequency component reduction signal to be coded as an input signal and a coded signal 14 as an output signal.

Next, the operation of the above embodiment will be described.

Pixel value signal 1 containing image pixel value information
Is input to the blocking means 2, the image is divided into horizontal and vertical lattice-shaped pixel blocks and output as pixel blocks 3.

Here, the pixel position signal 4 to be encoded is
It is a signal coded by determining whether or not to code from the transparency of the pixel value signal of the image.

When the pixel position signal 4 to be encoded is input to the effective block determination means 5, it is determined whether or not the block synchronized with the pixel block 3 contains a pixel value to be encoded. The signal based on the judgment is
The valid block determination means 5 outputs the control signal 6. When the control signal 6 and the pixel block 3 are input to the selecting means 7, and the pixel value to be coded for the pixel block 3 is included, the valid block determining means 5 causes the pixel block 3 to When it is determined that the pixel block to be coded is included, the pixel block 3
Is output from the selection means 7 as a pixel block 8 to be encoded. Further, when the valid block determination means 5 determines that the pixel block 3 does not include the pixel value to be encoded, the selection means 7 does not output the pixel block 8 to be encoded. When the pixel block 8 to be encoded and the pixel position signal 4 to be encoded output from the selecting means 7 are input to the pixel value generating means 9, the pixel block 8 to be encoded should be encoded. The average value of the pixel values of the pixels is calculated and output from the pixel value generation means 9 as a high frequency component reduction signal 10. When the high-frequency component reduction signal 10, the pixel block 8 to be encoded, and the pixel position signal 4 to be encoded are input to the blocking means 11, pixels that are not pixels to be encoded included in the pixel block to be encoded The average value is substituted for the value, and the blocking means 1 is used.
1 outputs the pixel block 12 to be encoded including the high frequency component reduction signal. When the pixel block 12 to be encoded including the high frequency component reduced signal is input to the encoding means 13, multi-level encoding using DCT is performed, and the encoding signal 13 is output from the encoding means 13. It

Here, FIG. 10 is a diagram showing that a value for reducing a high frequency component is stored in a pixel value which is not a pixel to be coded in this embodiment. As shown in the diagram on the right side of FIG. 10, pixels to be encoded are filled in with black, and pixels that are not to be encoded are filled with a mesh. The above-mentioned average value capable of reducing high frequency components is substituted for the pixels that are not filled with the mesh and are not the pixels to be encoded.

That is, in the present embodiment, the high frequency component can be reduced by substituting the value for reducing the high frequency component of the pixel block to be encoded into the pixel which is not the pixel to be encoded included in the pixel block to be encoded. It is an image signal encoding device capable of A method for substituting a value for reducing a high frequency component of a pixel block to be encoded into a pixel value that is not a pixel to be encoded and included in a pixel block to be encoded is a method according to claim 2, 3, 4, or 5.
It is also applicable to the present invention.

The multi-level coding in the coding means 13 is as follows.
Although the DCT is used, the present invention is not limited to this, and multilevel coding that combines orthogonal transformation and entropy coding may be used. In short, any multi-level encoding method that can efficiently perform multi-level encoding will do.

Although the average value of the pixel values to be coded is used as the high frequency component reducing method of the pixel value generating means, it is not limited to this and an interpolation value may be used. In short, any value can be used as long as it can reduce high frequency components.

Although the pixel value transparency is used as the means for determining whether or not the pixel is to be coded, the invention is not limited to this, and even the brightness with the pixel value transparency information superimposed thereon is used. Good. In short, it suffices if the information on the transmission state of the pixel value is included.

[0059]

As is apparent from the above description, the present invention according to claim 1 determines whether or not the image signal is a pixel region to be encoded, based on the transmission state of the pixel value.
By encoding the pixel area to be encoded by a predetermined encoding method based on the pixel position signal to be encoded obtained by encoding the determination result, the encoding of the pixel area which is not the pixel area to be encoded is omitted. And has an advantage that the efficiency of encoding can be improved.

Further, the image signal coding apparatus of the present invention according to claims 2, 3, 4, 5 and 6 can improve the coding efficiency.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment according to an image signal coding apparatus of the present invention according to claim 2;

FIG. 2 is a diagram showing pixel block formation according to the present embodiment.

FIG. 3 is a block diagram of an embodiment according to the image signal encoding device of the present invention of claim 3;

FIG. 4 is a diagram showing a large pixel block and a small pixel block according to the present embodiment.

FIG. 5 is a block diagram of an embodiment according to the image signal coding apparatus of the present invention of claim 4;

FIG. 6 is a diagram showing pixel blocking according to the present embodiment.

FIG. 7 is a block diagram of an embodiment according to the image signal coding apparatus of the present invention of claim 5;

FIG. 8 is a diagram showing a single block in this embodiment.

FIG. 9 is a block diagram of an embodiment according to the image signal coding apparatus of the present invention of claim 6;

FIG. 10 is a diagram showing that a value that reduces a high frequency component is stored in a pixel that is not a pixel to be encoded according to the present embodiment.

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] November 24, 1994

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0018

[Correction method] Change

[Correction content]

FIG. 3 is a block diagram of an embodiment according to the image signal coding apparatus of the present invention of claim 3. That is, the pixel value signal 3-1 is used as an input signal, and the large pixel block
3-3 as an output signal for large block forming means 3-2, and the pixel value signal 3-1 as an input signal for the small pixel block 3
- 5 a small block means 3-4 to the output signal and the pixel position signal 3-6 to be coded as an input signal, the control signal
Enable large block judging means and the output signal of the 3-8 3-7
And an effective small block determination means 3-9 which receives the pixel position signal 3-6 to be encoded as an input signal and outputs a control signal 3-10 as an output signal, and the large pixel block, the small pixel block and the control. Signal 3-8 and the control signal 3-10
Pixel block 3-12 to be coded with and as input signals
Is connected to the selection means 3-11 having an output signal.
The selecting means 3-11 uses the pixel block to be encoded, the control signal 3-8 and the control signal 3-10 as input signals and the encoded signal 3-14 as an output signal 3-. It is connected to 13.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0020

[Correction method] Change

[Correction content]

Pixel value signal 3 including image pixel value information
- 1 is inputted to the large blocking unit 3-2 is divided into large blocks of the image is composed of 16 × 16 pixels,
It is output as a large pixel block 3-3 . Further, the pixel value signal 3-1 is inputted to the small block means 3-4, wherein the image is divided into small blocks of 8 × 8 pixels, and output as a small pixel block 3-5.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0021

[Correction method] Change

[Correction content]

Here, the pixel position signal 3- to be encoded
Reference numeral 6 is a coded signal which is determined from the transparency of the pixel value signal of the image as to whether or not it should be coded.

[Procedure amendment 4]

[Document name to be amended] Statement

[Name of item to be corrected] 0022

[Correction method] Change

[Correction content]

The pixel position signal to be the coded 3- 6
Is input to the effective large block determination means 3-7 , it is determined whether or not the block synchronized with the large pixel block includes a pixel value to be encoded, and a signal based on the determination is The effective large block determination means 3-7 outputs the control signal 3-8 . Further, the pixel position signal 3-6 to be encoded is the effective small block determination means 3
- is input to 9, wherein for the small pixel blocks 3-5 and the synchronization block, whether to include the pixel value to be encoded is determined, a signal based on that determination, the effective small block judging means The control signal 3-10 is output from 3-9.

[Procedure Amendment 5]

[Document name to be amended] Statement

[Name of item to be corrected] 0023

[Correction method] Change

[Correction content]

[0023] The said control signal and the large pixel block 3 3 and the small pixel blocks 3-5 and the control signal 3 8 3
- 10 and is inputted to the selection unit 3 11, the large pixel block 3 3 and the small pixel block 3 7,
The pixel block 3-12 to be encoded is output under the control of the control signal 3-8 and the control signal 3-10 . That is, when it is determined that all of the four small pixel blocks included in the large pixel block 3-3 include pixels to be encoded, the large pixel block
3-3 is output as the pixel block 3-12 to be encoded from the selecting means 3-11 . In other cases than the above, when it is determined that at least one or more small pixel blocks among the four small pixel blocks included in the large pixel block 3-3 include pixels to be encoded. , only a small pixel block 3-5 it is determined to contain a pixel to be encoded, successively the selection means 3 11
Is output as a pixel block 3-12 to be encoded.

[Procedure correction 6]

[Document name to be amended] Statement

[Name of item to be corrected] 0024

[Correction method] Change

[Correction content]

[0024] The coding to be a pixel block 3 12
When the control signal 3-8 and the control signal 3-10 are input to the encoding means 3-13 , the pixel block 3-12 to be encoded is controlled by the control signal 3-8 and the control signal. 3-10 and encoded signal 3-14
Is output. That is, by said control signal 3 10 and the control signal 3 8 if all four small pixel blocks included in said large pixel block 3 3 is determined to contain a pixel to be encoded The pixel block 3-12 to be encoded is subjected to multi-value encoding by DCT corresponding to a large pixel block, and the encoding means 3-
The encoded signal 3-14 is output from 13. In other cases than the above, depending on the control signal 3-8 and the control signal 3-10, at least one of the four small pixel blocks included in the large pixel block 3-3 is small. If it is determined that the pixel block includes a pixel value to be encoded, the pixel block 3 to be encoded
- 12, multi-level encoding is performed by DCT corresponding to small pixel block, coded signal 3 14 is output from the encoding unit 3 13. In other cases, the encoded signal 3-14 is not output.

[Procedure Amendment 7]

[Document name to be amended] Statement

[Name of item to be corrected] 0027

[Correction method] Change

[Correction content]

[0027] Incidentally, the multi-level encoding in the encoding unit 3 13, was used DCT, not necessarily limited thereto, but may be multi-level encoding of a combination of a orthogonal transformation and entropy coding. In short, any multi-level encoding method that can efficiently perform multi-level encoding will do.

[Procedure Amendment 8]

[Document name to be amended] Statement

[Name of item to be corrected] 0030

[Correction method] Change

[Correction content]

FIG. 5 is a block diagram of one embodiment according to the image signal coding apparatus of the present invention of claim 4. That is, a block slicing means that uses the pixel value signal 5-1 as an input signal and the pixel block slice 5-3 as an output signal.
5-2 and the block start position determining means 5-5 which receives the pixel position signal 5-4 to be encoded as an input signal and outputs the control signal 5-6 as an output signal, the pixel block slice 5-5.
3 and the control signal 5-6 as an input signal, and a pixel block 5-8 to be encoded as an output signal
It is connected to 5-7 . The blocking means 5-7
Is a coding means 5 which uses the pixel block 5-8 to be coded as an input signal and the coded signal 5-10 as an output signal.
- is connected to 9.

[Procedure Amendment 9]

[Document name to be amended] Statement

[Name of item to be corrected] 0032

[Correction method] Change

[Correction content]

Pixel value signal 5 including image pixel value information
- 1 is inputted to the block slicing means 5-2, the image is divided into pixel blocks slice taken by the height is sliced by 16 pixels is output as pixel block slice 5-3 It

[Procedure Amendment 10]

[Document name to be amended] Statement

[Correction target item name] 0033

[Correction method] Change

[Correction content]

Here, the pixel position signal 5- to be encoded
Reference numeral 4 denotes a signal which has been encoded by determining whether or not it should be encoded from the transparency of the pixel value signal of the image.

[Procedure Amendment 11]

[Document name to be amended] Statement

[Correction target item name] 0034

[Correction method] Change

[Correction content]

Pixel position signal to be encoded 5-4
Is inputted to the block formation start position means 5-5 , the control signal 5-6 which is a signal corresponding to the start position of the pixel block formation consisting of 16 × 16 pixels with respect to the pixel block slice 5-3 , Blocking start position determining means
It is output from 5-5 . The pixel block slice 5-
3 and the control signal 5-6 are input to the blocking means 5-7 , the pixel block slice 5-3 is pixel-blocked with 16 × 16 pixels. That is, when it is determined by the control signal 5-8 that the pixel block slice 5-3 includes the pixel to be encoded, the pixel to be encoded is determined from the pixel position at which the pixel is first detected. Pixel blocking consisting of 16 × 16 pixels is performed. Then, among the pixel blocks obtained by dividing the pixel block slice, only the pixel blocks determined to include the pixel value to be encoded are sequentially output as the pixel block 5-8 to be encoded from the block forming means 5-7. To be done. When the pixel block 5-8 to be encoded is input to the encoding means 5-9 , DC
Multivalued encoding using T is performed, and an encoded signal 5-10 is output.

[Procedure Amendment 12]

[Document name to be amended] Statement

[Name of item to be corrected] 0037

[Correction method] Change

[Correction content]

The multi-level coding in the coding means 5-9 uses DCT, but not limited to this, multi-level coding in which orthogonal transform and entropy coding are combined may be used. In short, any multi-level encoding method that can efficiently perform multi-level encoding will do.

[Procedure Amendment 13]

[Document name to be amended] Statement

[Correction target item name] 0040

[Correction method] Change

[Correction content]

FIG. 7 is a block diagram of one embodiment according to the image signal coding apparatus of the present invention of claim 5. That is, the pixel position signal 7-4 to be encoded is used as an input signal,
A horizontal effective pixel range detecting means 7-5 to the output signal of the control signal 7-6, the pixel position signal 7-4 to be the coded as an input signal, the vertical effective pixel range and the output signal of the control signal 7 8 The detecting means 7-7 is connected to the selecting means 7-2 which receives the pixel value signal 7-1 as an input signal and outputs the single pixel block 7-3 to be encoded as an output signal. The connecting means 7-2 comprises a single pixel block 7 to be encoded.
- 3 as an input signal, it is connected to the encoding means 7 9, output signal a coded signal 7-10.

[Procedure Amendment 14]

[Document name to be amended] Statement

[Correction target item name] 0042

[Correction method] Change

[Correction content]

The pixel position signal 7-4 to be coded is a signal which is coded by judging whether or not to code from the transparency of the pixel value signal of the image.

[Procedure Amendment 15]

[Document name to be amended] Statement

[Correction target item name] 0043

[Correction method] Change

[Correction content]

Pixel position signal to be encoded 7-4
Is input to the horizontal effective pixel range detecting means 7-5 ,
Wherein the pixel position signal 7-4 to be encoded, the control signal based on the pixel position to be encoded to be first detected in the horizontal direction, the pixel position to be encoded that is last detected 7-
6 is output from the horizontal effective pixel range detecting means 7-5 . Further, the pixel position signal 7-4 to be encoded is
When input to the vertical effective pixel range detecting means 7-7 , from the pixel position signal 7-4 to be encoded, the pixel position to be encoded first detected in the vertical direction and the pixel position to be finally detected to be encoded. Control signal 7-8 based on pixel position
Is output from the vertical effective pixel range detecting means 7-7 .

[Procedure Amendment 16]

[Document name to be amended] Statement

[Correction target item name] 0044

[Correction method] Change

[Correction content]

Pixel value signal 7 including image pixel value information
- 1 and the control signal 7-6 and the control signal 7-8,
When it is input to the selection means 7-1 , the control signal 7-6 and the control signal 7-8 cause the pixel value signal 7-1 to be the smallest single pixel including the pixel value to be encoded. A block is constructed, and a single pixel block 7-3 to be encoded is output from the selecting means 7-1 . Even if the single pixel block 7-3 to be encoded is input to the encoding unit 7-9 that performs multi-level encoding by Wavelet encoding, which cannot encode a plurality of blocks, it is a single pixel block. It is possible to perform multi-level encoding by encoding,
The coded signal 7-10 is output from the coding means 7-9 .

[Procedure Amendment 17]

[Document name to be amended] Statement

[Correction target item name] 0047

[Correction method] Change

[Correction content]

[0047] Incidentally, the multi-level encoding in the encoding means 7-9 has been a Wavelet coding, not necessarily limited thereto, but may be multi-level encoding of a combination of a orthogonal transformation and entropy coding. In short, any multi-level encoding method that can efficiently perform multi-level encoding will do.

[Procedure 18]

[Document name to be amended] Statement

[Correction target item name] 0049

[Correction method] Change

[Correction content]

FIG. 9 is a block diagram of one embodiment according to the image signal coding apparatus of the present invention of claim 6. That is, the pixel value signal 9-1 is used as an input signal, and the pixel block 9
- 3 and blocking means 9-2 to the output signal and the pixel position signal 9 4 to be coded as an input signal, the control signal 9
The effective block determination means 9-5 having -6 as an output signal selects the pixel block 9-3 and the control signal 9-6 as input signals and the pixel block 9-8 to be encoded as an output signal. It is connected to means 9-7 . Pixel value generating means for inputting the selecting means 9-7 , the pixel position signal 9-4 to be encoded and the pixel block 9-8 to be encoded and the high frequency component reducing signal 9-10 as an output signal. 9-9 is the pixel position signal to be encoded
9-4, the pixel block to be encoded, and the high frequency component reduction signal 9-10 as input signals, and the pixel block 9-12 to be encoded including the high frequency component reduction signal as an output signal, a blocking means 9-. 11 is connected.
The blocking means 9-11 is connected to the encoding means 9-13 which uses the pixel block 9-12 to be encoded including the high frequency component reduced signal as an input signal and the encoded signal 9-14 as an output signal. ing.

[Procedure Amendment 19]

[Document name to be amended] Statement

[Correction target item name] 0051

[Correction method] Change

[Correction content]

Pixel value signal 9 including image pixel value information
When -1 is input to the blocking unit 9-2 , the image is divided into horizontal and vertical pixel blocks in a grid pattern and output as a pixel block 9-3 .

[Procedure amendment 20]

[Document name to be amended] Statement

[Correction target item name] 0052

[Correction method] Change

[Correction content]

Here, the pixel position signal 9- to be encoded
Reference numeral 4 denotes a signal which has been encoded by determining whether or not it should be encoded from the transparency of the pixel value signal of the image.

[Procedure correction 21]

[Document name to be amended] Statement

[Correction target item name] 0053

[Correction method] Change

[Correction content]

Pixel position signal to be encoded 9-4
Is input to the effective block determination means 9-5 , it is determined whether or not the block synchronized with the pixel block 9-3 includes a pixel value to be encoded, and a signal based on the determination is The effective block determination means 9-5 outputs the control signal 9-6 . The control signal 9-6
When the pixel block 9-3 and the pixel block 9-3 are input to the selection unit 9-7, and the pixel value to be coded for the pixel block 9-3 is included, the effective block determination unit 9-5 causes the pixel block 9-3 to be processed. when the pixel blocks 9-3, which is determined to contain pixel values to be coded, the pixel blocks 9-3
Is a pixel block to be encoded by the selecting means 9-7.
It is output as 9-8 . Moreover, the the valid block determination unit 9 5, the pixel blocks 9-3, when it is determined not to include the pixel values to be coded, the pixel block 9 8 to be encoded from said selecting means 9- 7 Is not output. When the pixel block 9-8 to be coded and the pixel position signal 9-4 to be coded output from the selecting means 9-7 are input to the pixel value generating means 9-9 , the pixel to be coded The average value of the pixel values of the pixels to be encoded included in the block 9-8 is calculated and output from the pixel value generating means 9-9 as a high frequency component reduction signal 9-10 . When the high frequency component reduction signal 9-10, the pixel block 9-8 to be encoded, and the pixel position signal 9-4 to be encoded are input to the blocking means 9-11 , the pixel block to be encoded. The average value is substituted for a pixel value that is not a pixel to be encoded,
The block forming means 9-11 outputs a pixel block 9-12 to be coded that includes a high frequency component reduction signal. When the pixel block 9-12 to be encoded including the high frequency component reduced signal is input to the encoding means 9-13 , multi-value encoding using DCT is performed, and the encoding means 9-13 encodes it. The converted signals 9-14 are output.

[Procedure correction 22]

[Document name to be amended] Statement

[Correction target item name] 0056

[Correction method] Change

[Correction content]

The multi-level coding in the coding means 9-13 uses the DCT, but the multi-level coding is not limited to this and may be multi-level coding in which orthogonal transform and entropy coding are combined. In short, any multi-level encoding method that can efficiently perform multi-level encoding will do.

[Procedure amendment 23]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 3

[Correction method] Change

[Correction content]

[Figure 3]

[Procedure correction 24]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 5

[Correction method] Change

[Correction content]

[Figure 5]

[Procedure correction 25]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 7

[Correction method] Change

[Correction content]

[Figure 7]

[Procedure Amendment 26]

[Document name to be corrected] Drawing

[Correction target item name] Figure 9

[Correction method] Change

[Correction content]

[Figure 9]

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Office reference number FI Technical display location H04B 14/04 Z H04N 1/41 B

Claims (6)

[Claims] 1. A pixel to be encoded based on a pixel position signal to be encoded, which is determined by determining whether the image signal is in a pixel region to be encoded based on a pixel value transmission state and encoding the determination result. An image signal encoding method, characterized in that an area is encoded by a predetermined encoding method. 2. A block forming means for dividing an image signal into pixel blocks made up of a set of predetermined pixels, and whether or not it is a pixel region to be encoded is determined by the transmission state of pixel values, and the determination result is encoded. Based on the obtained pixel position signal to be encoded, an effective block determination means for determining whether or not the pixel block includes a pixel to be encoded, and only the pixel block determined to include a pixel to be encoded are selected. Image signal coding, which comprises: a selection unit that outputs the pixel block output from the selection unit and an encoding unit that outputs the encoded signal by encoding the pixel block output from the selection unit by a predetermined encoding method. apparatus. 3. A large block forming means for dividing an image signal into large pixel blocks each consisting of a set of predetermined pixels,
A small block forming unit that divides into a small pixel block composed of a set of a predetermined number of pixels smaller than the large pixel block, and it is determined whether or not the pixel region is to be encoded by the transmission state of the pixel value, and the determination result is encoded. Based on the obtained pixel position signal to be encoded, the effective large block determination means for determining whether or not the large pixel block includes a pixel to be encoded, and the small pixel block based on the pixel position signal to be encoded Effective small block determination means for determining whether or not a pixel to be encoded is included, and the effective large block if it is determined as a result of the effective large block determination means or the effective small block determination means to include a pixel to be encoded Based on the result of the determining means or the effective small block determining means, the effective large block determining means or the effective small block is determined. Selecting means for selecting and outputting one pixel block of the judging means; and outputting a coded signal by coding the pixel block selected by the selecting means by a predetermined coding method corresponding to the size of the block. An image signal coding apparatus, comprising: 4. A block slicing means for dividing an image signal into pixel block slices each consisting of a set of predetermined pixels having a constant height, and whether the pixel region is a pixel region to be coded or not is determined by a transmission state of pixel values. A blocking start position determining means for detecting a position which is a starting point of a horizontal row of pixels to be encoded included in the pixel block slice, based on a pixel position signal to be encoded obtained by encoding the determination result. Blocking means for dividing into pixel blocks with a width of a predetermined number of pixels from the starting point, and coding means for coding only the pixel blocks including pixels to be coded by a predetermined coding method and outputting a coded signal. An image signal encoding device comprising: 5. A pixel to be coded is decided based on a pixel position signal to be coded, which is determined by coding the decision result based on the transmissive state of the pixel value, and coding the decision result. Horizontal effective pixel range detecting means for detecting the start and end positions of the horizontal row, and the positions of the start and end points of the vertical row of the pixel to be encoded based on the pixel position signal to be encoded. Vertical effective pixel range detecting means, selecting means for selecting only the pixels within the range specified by the horizontal effective pixel range detecting means and the vertical effective pixel range detecting means, and the pixel value of the pixel selected by the selecting means An image signal encoding apparatus, comprising: an encoding unit that encodes only the encoded signal by a predetermined encoding method and outputs an encoded signal. 6. A first blocking unit that divides an image signal into pixel blocks made up of a set of predetermined pixels, and whether the pixel region is a pixel region to be encoded is determined based on the transmission state of pixel values, and the determination result is obtained. Based on the pixel position signal to be encoded obtained by encoding the effective block determining means for determining whether or not the pixel block includes a pixel to be encoded, and the pixel block determined to include a pixel to be encoded Selecting means for selecting and outputting only the pixel value to be encoded included in the pixel block output from the selecting means is calculated by a predetermined function capable of reducing high frequency components, and the calculated value is calculated. Pixel value generation means for substituting pixel values that are not pixels to be encoded included in the pixel block, and encoding included in the pixel block selected by the selection means. Second blocking means for forming a pixel block to be coded by combining a power pixel and a pixel which is not a pixel to be coded generated by the pixel value generating means, and the pixel block to be coded by a predetermined coding method. An image signal encoding apparatus, comprising: an encoding unit that encodes and outputs an encoded signal.