JPH10327405A - Image encoding/decoding device and method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform optimum wavelet transformation corresponding to the property of the local part of images and to improve encoding efficiency by performing local wavelet transformation to a specified frequency component of divided image signals. SOLUTION: Relating to the local wavelet transformation means 13-i (i)=1 2,...4} of four stages at the rear part of a block division means 12, to respectively inputted image blocks, the frequency band of the input image blocks is divided further by the different methods of division. The local wavelet transformation means (13-1 and 13-2) for performing only one-dimensional wavelet transformation are constituted of a wavelet filter for performing the one- dimensional wavelet transformation of one stage and the memory of one stage. Then, in a switching means 16, a code amount S15-i which is also the output of the encoding means of respective stages to be inputted is counted and the code of the encoding means of a smallest code amount is selected and outputted together with local wavelet transformation information.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for encoding / decoding a still image or a moving image, and more particularly to an efficient image encoding.

[0002]

2. Description of the Related Art Conventionally, there has been a technique described in the following literature as a technique in such a field.

Reference: Jerome M. Shapiro, Embedded Im
age Coding Using Zerotrees of Wavelet Coefficient
s, IEEE Trans. SP, Vol.41, No.12, DECEMBER 1993.
pp.3445-3462.

[0004] The above-mentioned document describes a method of encoding and decoding an image using a wavelet transform.

The configuration and operation of a conventional image coding method will be described below with reference to FIG. This conventional image coding method includes a wavelet transform unit 21 for performing a wavelet transform on a two-dimensional image signal, a block dividing unit 22 for dividing a wavelet-transformed image into blocks having a tree structure, It comprises a quantizing means 23 for quantizing and an encoding means 24 for encoding the quantized image signal.

[0006] The input image signal S20 is connected to the wavelet transform means 21, the output S21 of the wavelet transform means 21 is connected to the block dividing means 22, and the output S22 of the block dividing means 22 is connected to the quantizing means 23. The output S23 of the means 23 is connected to the encoding means 24, and the output S24 of the encoding means 24 is connected to an external terminal.

The wavelet transform means 21 for performing a wavelet transform on the two-dimensional image signal, as shown in FIG.
It is configured by connecting a wavelet filter for performing one-dimensional wavelet transform and a memory in multiple stages.

In FIG. 3, when a two-dimensional image signal S30 is input, first, a first-stage wavelet filter 31
Then, a one-dimensional horizontal (or vertical) wavelet transform is performed on the input image or the output S34-1 from the second-stage memory 34, and the low-frequency component S31-1 and the high-frequency component S31-2 are converted. Output to the first stage memory 32. Second stage wavelet filters 33-1 and 33
-2, the low-frequency component S output from the memory of the first stage
The vertical (or horizontal) one-dimensional wavelet transform is performed on each of the 32-1 and the high-frequency components S32-2, and the low-frequency components S33-1 and S33-3 and the high-frequency components S33-2 and S33-4 are respectively performed. To the second stage memory 3
4 is output. The second-stage memory 34 stores the low-frequency component S34-1 in the vertical and horizontal directions of the input image in the first stage.
It outputs the wavelet filter 31 of the stage and all the components S34-2 to external terminals.

The wavelet filter includes a pair of low-pass filters as shown in FIG.
r) 41 and a high-pass filter 42. In FIG. 4, when the one-dimensional signal S40 is input, the low-pass filter 41 applies a low-pass filter to the input signal as shown in Expression 1, sub-samples the output data by half, and outputs the signal S41. The high-pass filter 42 applies a high-pass filter to the input signal as in Expression 2, sub-samples the output data by half, and outputs a signal S42. In Equations 1 and 2,
h (k) and g (k) indicate the coefficients of the low-pass filter and the high-pass filter, respectively, S1 indicates the input signal, and Sl + 1 and Wl + 1 indicate the outputs of the low-pass filter and the high-pass filter, respectively.

[0010] By configuring the wavelet transform means as shown in FIG. 3, it is possible to repeatedly perform the wavelet transform on the low-frequency component. For example, an image obtained by performing the three-stage wavelet transform has a low-frequency component as shown in FIG. The component is divided finely (small), and the high frequency component is coarse (large)
Divided.

The block dividing means 22 of FIG. 2 extracts corresponding pixel components from the wavelet-transformed image S21 in accordance with the tree structure of the image signal to form a block, and outputs the block data S22. . For example, as shown in FIG. 6A, the tree structure of the pixels of the image subjected to the three-stage wavelet transform as shown in FIG. 5 has three child pixels (H in the first parent pixel (one pixel in LL1)).
L1, LH1, and HH1 each have one pixel), and each child pixel has four more child pixels (HL2, LH
2, HH2 each having four pixels), and these child pixels further have four child pixels (HL3, LH3,
HH3 has four pixels each). This parent-child structure is called a tree structure. The block dividing means 22 collects these parent and child into one image block as shown in FIG.

The quantization means 23 quantizes the input image block S22 and outputs a quantization index. For example, assuming that an input pixel is X and a quantization coefficient is Q, the quantization means uses a quantization index Y =
X / Q is output.

[0013] The encoding means 24 encodes the image divided into blocks and quantized. As an encoding method, for example, there is a method of performing one-dimensional scanning in order from a parent to a child and performing run-length encoding. Alternatively, there is a method in which it is determined whether or not a parent has a zero root (whether all the children and grandchildren of the parent are zero), and when the parent has a zero root, the encoding of the children is skipped and encoded.

The configuration and operation of a conventional image decoding method are as follows.

FIG. 13 shows the configuration of a conventional image decoding method. It comprises a decoding means 25, an inverse quantization means 26, an image construction means 27, and an inverse wavelet transform means 28.

The encoded signal S24 of the image is connected to the decoding means 25, the output S25 of the decoding means 25 is connected to the inverse quantization means 26, and the output S26 of the inverse quantization means 26
Is connected to the image composing means 27, and the output S27 of the image composing means 27 is connected to the inverse wavelet transform means 28,
The output S28 of the inverse wavelet transform means is connected to an external terminal.

When the encoded signal S24 of the image is input, the decoding means 25 performs the reverse operation of the encoding means 24 and decodes the image signal. For example, for a signal that has been run-length coded with a length of zero and a non-zero value in the encoding means, the length of the zero and the value of the value of the non-zero signal are calculated from the signal and the image is calculated. Restore the signal.

In the inverse quantization means 26, the operation is the reverse of that of the quantization means 23. For example, in the quantization means, Y (= X / Q)
Is output by the inverse quantization means, X ′ = Q ·
Outputs Y.

The image composing means 27 operates in the reverse manner to the block dividing means 22, and returns the corresponding pixels from the image block shown in FIG. 6B to constitute the image frame shown in FIG.

The inverse wavelet transform means 28 performs the reverse operation of the wavelet transform means 21 to restore the wavelet-transformed image.

By performing a decoding operation reverse to this series of encoding methods, an encoded image can be restored.

[0022]

However, in the conventional image coding method, after the wavelet transform, for example, as shown in FIG. 5, in the band such as HL2 and HL3, the band is a high frequency band in the horizontal direction, but is in the vertical direction. Because of the low frequency band, there is a high possibility that a high correlation is still left in the vertical direction, which causes a decrease in conversion compression efficiency. Further, the conventional wavelet transform method performs the same wavelet transform on the entire image, so that there is a problem that it is not possible to adaptively cope with local changes in the properties of the image. In addition, DCT is often used in image coding.
Although there is a method using (discrete cosine transform), since the conversion is performed after dividing the entire image into blocks, there is a problem that block noise occurs due to blocking.

[0023]

[Means for Solving the Problems]

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION

<< Specific Example 1 >><Structure> Hereinafter, a specific example 1 according to the present invention will be described in detail with reference to the drawings. FIG. 1 is a configuration diagram of an image encoding method according to Embodiment 1 of the present invention. The image encoding method according to the first embodiment of the present invention is the same as the image encoding method according to the prior art, except that the block encoding unit and the quantization unit are connected in parallel to the quantization unit and the encoding unit behind the block division unit. A four-stage local wavelet transform unit for further performing one-dimensional wavelet on the component of the vertical direction or both the horizontal and vertical components, a quantizing unit for quantizing the image block after the local wavelet transform, Encoding means for encoding the encoded image block, and switching means for selecting one output from the outputs of the 4 + 1 encoding means including the conventional encoding means. I have.

In FIG. 1, an input image signal S10 is connected to a wavelet transform means 11, an output S11 of the wavelet transform means 11 is connected to a block dividing means 12, and an output S12 of the block dividing means 12 is connected to a quantizing means 14-. 0 and 4-stage local wavelet transform means 13
-I (i = 1, 2,... 4) and 4
Stage local wavelet transform means 13-i (i = 1,
2,. . . Each output S13-i of 4) is connected to the corresponding quantizing means 14-i, and each output S14-i of the 4 + 1-stage quantizing means 14-i is connected to the corresponding encoding means 15-i. connected to i, 4 + 1
Each output S15-i of the stage encoding means 15-i
Is connected to the switching means 16, and the output S1 of the switching means 16
6 is connected to an external terminal.

<Operation> The wavelet transform means 11 and the block dividing means 12 have the same functions as those of the prior art and perform the same operations, so that the description will be omitted.

Four-stage local wavelet transform means 13-
In i (i = 1, 2,..., 4), the frequency band of the input image block is further divided by a different division method for each input image block. As a first example, the first-stage local wavelet transform unit 13-1
Then, the horizontal components HL2 and HL are further added to the input image block having the frequency band as shown in FIG.
3 is subjected to a one-dimensional wavelet transform in the vertical direction, and subdivided into frequency bands as shown in FIG. Here, the horizontal component indicates a frequency band that is a high frequency band in the horizontal direction but is a low frequency band in the vertical direction.

As a second example, the local wavelet transform means 13-2 at the second stage converts the input image block having the frequency band shown in FIG. 5 into the vertical components LH2 and LH3. Then, one-dimensional wavelet transform is performed in the horizontal direction, and the frequency band is subdivided as shown in FIG. Here, the vertical component indicates a frequency band that is a high frequency band in the vertical direction but is a low frequency band in the horizontal direction.

As a third example, the third-stage local wavelet transform means 13-3 further adds horizontal components HL2 and HL3 and a vertical component to an input image block having a frequency band as shown in FIG. Directional components LH2 and L
One-dimensional wavelet transform by the first-stage and second-stage local wavelet transform means is performed on H3, and subdivision of the frequency band is performed as shown in FIG. As a fourth example, the fourth-stage local wavelet transform unit 13-4
Then, for an input image block having a frequency band as shown in FIG. 5, two more frequency components are added so that all the frequency components have the same band width as shown in FIG. Performs a dimensional wavelet transform and subdivides the frequency band.

A local wavelet transform means (for example, 1-dimensional wavelet transform) which performs only one-dimensional wavelet transform.
3-1 and 13-2) are wavelet filters 71 for performing one-stage one-dimensional wavelet transform as shown in FIG.
And one-stage memory 81. The wavelet filter 71 performs one-dimensional wavelet transform on the input image signal and outputs the low-frequency component S71-1 and the high-frequency component S71-2 to the memory 72, as in the above-described wavelet filter. Memory 72
Is output to the one-dimensional wavelet filter 71 again. By repeating the wavelet transform, a one-dimensional wavelet transform of an arbitrary number of stages can be performed. Also, 13
Local wavelet transform means for performing one-dimensional wavelet transform such as -3 on the vertical and horizontal components, respectively, is obtained by connecting the local wavelet transform means for performing only one-dimensional wavelet transform in two stages in parallel. I just need. Further, the local wavelet transform means for performing the two-dimensional wavelet transform can be realized with the same configuration as the conventional wavelet transform.

The quantizing means 14-i of each stage and the encoding means 15-i of each stage have the same functions as those of the prior art and operate in the same manner, so that the description will be omitted.

The switching means 16 counts the code amount S15-i which is the output of the remarkable coding means, selects the code of the coding means having the smallest code amount, and also includes the local wavelet transform information. Output. This local wavelet transform information is output by the local wavelet transform means 13-i. Alternatively, the local wavelet transform information may be selected and output by the switching unit 16 depending on which encoding unit 15-i is selected.

<Effects> As described above, according to the first embodiment of the present invention, by adding the local wavelet transform means, it is possible to perform the optimal wavelet transform according to the local properties of the image. Further, the coding efficiency can be further improved.

<< Embodiment 2 >><Configuration> Hereinafter, Embodiment 2 of the present invention will be described in detail with reference to the drawings. As shown in FIG. 12, in the image encoding method according to the second embodiment of the present invention, in the image encoding method according to the first embodiment of the present invention, the switching unit is placed after the quantization unit, and the encoding unit is arranged in one stage. This is a reduced configuration.

<Operation> In the switching means of the second embodiment of the present invention, the coding efficiency is estimated by using the quantization error by the quantization means at each stage and the size of the image signal after quantization or the number of zeros. In addition, it has a function of selecting and outputting the highest coding efficiency. For example, using the product of the number of non-zeros and the quantization error as a criterion, estimating the output of the quantization means having the smallest product as having the best coding efficiency, selecting and outputting the output of the quantization means To do.

<Effects> As described above, according to the second embodiment of the present invention, in the first embodiment of the present invention, the switching means is placed after the quantizing means, so that the encoding means is one stage. Therefore, the device can be simplified and the device can be simplified.

<< Embodiment 3 >><Configuration> Hereinafter, Embodiment 3 according to the present invention will be described in detail with reference to the drawings. The image decoding method according to the third embodiment of the present invention includes:
As shown in FIG. 14, in a conventional image decoding method, a local wavelet inverse transform unit 29 is inserted between an inverse quantization unit 26 and an image construction unit 27.

<Operation> In the image decoding method according to the third embodiment of the present invention, the decoding means 25, the inverse quantization means 26, the image construction means 27 and the inverse wavelet transform means 28 have the same functions as those of the prior art. Since the same operation is performed, the description is omitted.

In the local wavelet inverse transform means 29,
For the input dequantized image block, perform an operation opposite to the local wavelet transform according to the information of the local wavelet transform method selected at the time of image encoding,
The local wavelet transform image block is restored by performing the inverse wavelet transform. For example, on the encoding side, when only the horizontal frequency component is subjected to the vertical one-dimensional wavelet transform as shown in FIG. 7 for the block of interest, the local wavelet inverse transform means converts the horizontal frequency component to the horizontal frequency component. Only the inverse one-dimensional wavelet transform in the vertical direction is performed on the image block, and the image block is returned to the configuration in FIG.

<Effects> As described above, according to the third embodiment of the present invention, in the conventional image decoding method, the local wavelet inverse transform means is inserted between the inverse quantization means and the image construction means. By doing so, the images encoded by the image encoding methods of the first and second specific examples of the present invention can be restored.

<< Embodiment 4 >><Structure> Embodiment 4 of the present invention will be described below in detail with reference to the accompanying drawings. As shown in FIG. 15, the image encoding method according to the fourth embodiment of the present invention is different from the image encoding method according to the first embodiment of the present invention in that the switching means is eliminated, the local wavelet transform means is reduced to one stage, A configuration is provided in which property detecting means is provided, the property of the block is detected from the output of the block dividing means, and the local wavelet transform means is thereby controlled.

<Operation> In the local property detecting means 18 according to the fourth embodiment of the present invention, for each image block output from the block dividing means 12, for example, the vertical components HL2 and HL3 are A correlation is determined, and when the correlation is higher than a specified value, the horizontal components HL2 and H
The control signal s18 is output to the local wavelet transform unit 13 so as to perform one-dimensional longitudinal wavelet transform on L3. At the same time, the vertical components LH2 and LH
3 is obtained, and when the correlation is higher than a specified value, the control signal s18 is locally applied to perform a one-dimensional horizontal wavelet transform on the vertical components LH2 and LH3 of the block. Output to the wavelet transform means 13. As a method of calculating the correlation, for example, there is a method of using a product obtained by cumulatively adding the products of adjacent image signals and dividing the sum by the sum of squares of the image signals.

In the local wavelet transform means 13, the image block input from the block dividing means 12 is shifted in the horizontal direction, the vertical direction, or both the horizontal and vertical directions in accordance with the control signal s 18 input from the local property detecting means 18. Either one-dimensional wavelet transform is performed and output, or input is output as it is.

Although the local property detecting means 18 detects the local property by calculating the correlation with respect to the image signal output from the block dividing means 12, it is assumed that the image signal is input separately to obtain the correlation. Is also good.

<Effects> As described above, according to the fourth embodiment of the present invention, in the first embodiment of the present invention, the switching means is eliminated and the local wavelet transform means is provided in one stage. Significant simplification can be realized.

<< Embodiment 5 >><Structure> Hereinafter, Embodiment 5 of the present invention will be described in detail with reference to the drawings. As shown in FIG. 16, the image coding method according to the fifth embodiment of the present invention is similar to the image coding method according to the fourth embodiment of the present invention except that an inverse quantization unit, a local inverse wavelet transform unit, and a memory are provided. The output of the quantization means is connected to the inverse quantization means, the output of the inverse quantization means is connected to the local wavelet inverse transform means, the output of the local wavelet inverse transform means is output to the memory, and the output of the memory is the local property detecting means. , And outputs the output of the local property detecting means to the local wavelet transform means and the local wavelet inverse transform means.

<Operation> The inverse quantization means 26 of the fifth embodiment of the present invention has the same function as the inverse quantization means of the third embodiment, and the image signal quantized by the quantization means 14 is inverted. Quantize and restore.

In the local wavelet inverse transform means 13,
It has a function similar to that of the local wavelet inverse transform unit of the specific example 3, and according to the control signal s18 output from the local property detecting unit 18 described later, the image block which has been subjected to the local wavelet transform by the control signal s18. Perform local wavelet inverse transform to restore image blocks.

The memory 30 stores the image blocks restored by the local wavelet inverse transform means 29.

The local property detecting means 18 stores a target image block to be encoded at the moment in the memory 30
More specifically, the correlation between the horizontal component and the vertical component of the compressed and decompressed image block adjacent to the target block is described in the fourth embodiment.
And outputs a control signal s18 to the local wavelet transform means 13 and the local wavelet inverse transform means 29 so as to further perform one-dimensional wavelet transform and inverse transform in the direction of the large correlation.

<Effects> As described above, according to the fifth embodiment of the present invention, in the fourth embodiment of the present invention, the local property detection is performed using the compressed and decompressed image block near the target image block. By controlling the local wavelet transform means, it becomes possible to control the local wavelet inverse transform means on the decoding side as well, eliminating the need to transmit the control signal, and further improving the coding efficiency. .

<Embodiment 6><Structure> Embodiment 6 according to the present invention will be described below in detail with reference to the drawings. As shown in FIG. 17, the image decoding method according to the sixth embodiment of the present invention is different from the image decoding method according to the third embodiment in that a memory and a local property detecting unit are provided and an output of the local wavelet inverse transform unit is stored in a memory , The output of the memory is output to the local property detection means, and the output of the local property detection means is output to the local wavelet inverse transform means.

<Operation> In the memory 30 according to the sixth embodiment of the present invention, the image block restored by the local wavelet inverse transform means 29 is stored.

The local property detecting means 18 stores a target image block to be encoded
More specifically, the correlation between the horizontal component and the vertical component of the compressed and decompressed image block adjacent to the target block is described in the fourth embodiment.
To the local wavelet inverse transform means 29 so as to further perform one-dimensional wavelet transform and inverse transform in the direction in which the correlation is large.
8 is output.

<Effects> As described above, according to the sixth embodiment of the present invention, the local property detection is performed using the compressed and decompressed image block adjacent to the image block of interest to control the local wavelet inverse transform means. By doing so, the same control as that for the local wavelet transform means of the embodiment 5 of the present invention can be performed, and the image signal encoded by the embodiment 5 of the present invention can be decoded without a control signal.

[0056]

As described above, according to the image encoding apparatus of the present invention, by providing the local wavelet transform means, it is possible to perform the optimal wavelet transform according to the local properties of the image. Further improvement of the efficiency of the construction can be realized. In addition, by arranging the switching means behind the quantization means, the number of encoding means can be reduced to one, and the apparatus can be simplified.

According to the image decoding apparatus of the present invention, the local wavelet transform block is restored by the local wavelet transform information by providing the local wavelet inverse transform means, and the image is decoded. For this reason,
This has the effect that good image decoding without block noise can be realized.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an image encoding method according to Embodiment 1 of the present invention.

FIG. 2 is a configuration diagram of a conventional image encoding method.

FIG. 3 is a configuration diagram of a wavelet transform unit.

FIG. 4 is a configuration diagram of a wavelet filter.

FIG. 5 is a band configuration diagram of a conventional wavelet transform.

FIG. 6 is an explanatory diagram of a block dividing unit.

FIG. 7 is a frequency band division diagram of a first example of the local wavelet transform of the present invention.

FIG. 8 is a frequency band division diagram of a second example of the local wavelet transform of the present invention.

FIG. 9 is a frequency band division diagram of a third example of the local wavelet transform of the present invention.

FIG. 10 is a frequency band division diagram of a fourth example of the local wavelet transform of the present invention.

FIG. 11 is a configuration diagram of an example of a local wavelet transform.

FIG. 12 is a configuration diagram of an image encoding method according to Embodiment 2 of the present invention.

FIG. 13 is a configuration diagram of a conventional image decoding method.

FIG. 14 is a configuration diagram of an image decoding method according to Embodiment 3 of the present invention.

FIG. 15 is a configuration diagram of an image encoding method according to Embodiment 4 of the present invention.

FIG. 16 is a configuration diagram of an image encoding method according to Embodiment 5 of the present invention.

FIG. 17 is a configuration diagram of an image decoding method according to Embodiment 6 of the present invention.

[Explanation of symbols]

 11, 21 Wavelet transform means 12, 22 Block dividing means 13-1 to 13-4 Local wavelet transform means 14-0 to 14-4, 23 Quantization means 15-0 to 15-4, 16 24 Encoding means 16 Switching Means 18, local property detecting means 31, 33-1, 33-2 Wavelet filters 30, 32, 34 Memory 41 Low-pass filter 42 High-pass filter 25 Decoding means 26 Inverse quantization means 27 Image construction means 28 Wavelet inverse transform means 29 Local wavelet Inversion means

Claims (22)

[Claims] A wavelet transform unit that performs a wavelet transform on a two-dimensional image signal; a block dividing unit that divides the image signal subjected to the wavelet transform by the wavelet transform unit into blocks; N (n: positive integer) -stage local wavelet transform means for performing local wavelet transform on a specific frequency component; image signals divided by the block dividing means; and n-stage local wavelet transform means. N + 1 stages of quantizing means for quantizing the image signal obtained, n + 1 stages of encoding means for encoding the image signal quantized by the n + 1 stage quantization means, and encoding by the n + 1 stage encoding means. Switching means for selecting and outputting one-stage output from the converted image signal The image encoding device characterized by comprising a. 2. A wavelet transform unit that performs a wavelet transform on a two-dimensional image signal, a block dividing unit that divides the image signal that has been subjected to the wavelet transform by the wavelet transform unit into blocks, and an image signal that is divided by the block dividing unit. N (n: positive integer) stages of local wavelet transform means for performing local wavelet transform on a specific frequency component; an image signal divided by the block dividing means; and the n-stage local wavelet transformed image signal N + 1 stages of quantizing means for quantizing the image signal, switching means for selecting and outputting one stage output from the image signals quantized by the n + 1 stage quantizing means, and an image signal outputted by the switching means Encoding means for encoding Place. 3. The local wavelet transform means of n stages performs local wavelet transform on a horizontal component, a vertical component, a horizontal and a vertical component, and all components, respectively. Item 3. The image encoding device according to item 1 or 2. 4. The image encoding apparatus according to claim 1, wherein said local wavelet transform means of n stages outputs local wavelet transform information. 5. The image encoding apparatus according to claim 1, wherein the switching unit outputs local wavelet transform information according to the output of the selected one stage. 6. A decoding means for decoding a block-divided and encoded two-dimensional image signal, an inverse quantization means for inversely quantizing a signal of an image block decoded by the decoding means, and the inverse quantization means A local wavelet inverse transform unit that performs a local wavelet inverse transform according to the local wavelet transform information on the image block signal inversely quantized by the image block signal. An image decoding apparatus comprising: an image forming unit that forms a frame; and an inverse wavelet transform unit that performs two-dimensional inverse wavelet transform on the image frame formed by the image forming unit. 7. A wavelet transform unit for performing a wavelet transform on a two-dimensional image signal, a block dividing unit for dividing an image signal subjected to the wavelet transform by the wavelet transform unit into blocks, and determining a correlation of the image signal in a specific direction. A local property detecting means for detecting a local property and outputting a control signal according to the control signal output by the local property detecting means for the image signal divided by the block dividing means; Local wavelet transform means for performing local wavelet transform, and quantizing means for quantizing the image signal divided by the block dividing means and the image signal transformed by the local wavelet transform means. Code to encode the image signal Image encoding apparatus comprising: the means. 8. A wavelet transform unit that performs a wavelet transform on a two-dimensional image signal, a block dividing unit that divides the image signal subjected to the wavelet transform by the wavelet transform unit into blocks, and an image signal that is divided by the block dividing unit. On the other hand, according to a control signal output by the local property detecting means, a local wavelet transform means for performing a local wavelet transform on a specific frequency component, and an image signal divided by the block dividing means and a local wavelet transform means Quantization means for quantizing the image signal, encoding means for encoding the image signal quantized by the quantization means, and inverse quantization for inversely quantizing the image signal quantized by the quantization means. Quantization means, and the dequantized image A local wavelet inverse transform unit that performs a local wavelet inverse transform on a specific frequency component of the signal according to a control signal output by the local property detecting unit; A memory for storing the converted image signal, wherein the local property detecting means reads out an image signal of a block adjacent to the image block of interest to be encoded from the memory, and correlates a specific frequency component of the image signal in a specific direction. An image coding apparatus characterized in that a local property is detected by obtaining a property and a control signal is output. 9. A decoding unit for decoding a two-dimensional image signal divided and encoded by a block, an inverse quantization unit for inversely quantizing a signal of an image block decoded by the decoding unit, and the inverse quantization unit A local wavelet inverse transform unit that performs a local wavelet inverse transform on the signal of the image block dequantized by the local property detecting unit according to a control signal output from the local property detecting unit; A memory storing the inversely transformed image signal; and reading out the image signal of a block adjacent to the image block of interest to be decoded from the memory and calculating the correlation in a specific direction of a specific frequency component of the image signal to obtain a local property. Local property detecting means for detecting and outputting a control signal; Image constructing means for constructing an image frame from the image block signal inversely transformed by the above, and wavelet inverse transform means for performing two-dimensional inverse wavelet transform on the image frame constituted by the image constructing means. An image decoding apparatus characterized by the above-mentioned. 10. The local property detecting means, when a vertical correlation value of a horizontal low frequency component of an input image block is larger than a specified value, a vertical low frequency component of the input image block. A control signal is output so as to perform a primary wavelet transform, and when a horizontal correlation value of a vertical low frequency component of an input image block is larger than a predetermined value, a horizontal low frequency component is 10. The image encoding device according to claim 7, wherein a control signal is output so as to perform the first-order wavelet transform. 11. An image encoding / decoding apparatus comprising: the image encoding apparatus according to claim 1; and the image decoding apparatus according to claim 6. Description: . 12. An image encoding / decoding apparatus comprising: the image encoding apparatus according to claim 8; and the image decoding apparatus according to claim 9. 13. A wavelet transform of a two-dimensional image signal, dividing the wavelet-transformed image signal into blocks, performing a local wavelet transform on a specific frequency component of the divided image signal, Quantizing the converted image signal and the converted image signal, encoding the quantized image signal, and selecting and outputting one stage of output from the encoded image signal. Encoding method. 14. A wavelet transform of a two-dimensional image signal, dividing the wavelet-transformed image signal into blocks, performing a local wavelet transform on a specific frequency component of the divided image signal, Quantizing the converted image signal and the converted image signal, selecting and outputting one stage of output from the quantized image signal, and encoding the encoded image signal. Image coding method. 15. The local wavelet transform according to claim 13, wherein the local wavelet transform is performed on a horizontal component, a vertical component, a horizontal and vertical component, and all components. 2. The image encoding method according to 1., 16. The image encoding method according to claim 13, wherein the local wavelet transform outputs local wavelet transform information. 17. The image encoding method according to claim 13, wherein local wavelet transform information according to the selected one-stage output is output. 18. Decoding a block-divided and encoded two-dimensional image signal, dequantizing the decoded image block signal, and applying the local wavelet to the dequantized image block signal. Performing local wavelet inverse transform according to the transform information, constructing an image frame from the inversely transformed image block signal, and performing two-dimensional inverse wavelet transform on the image frame constructed by the image constructing means. Image decoding method. 19. A local property is detected by performing a wavelet transform on a two-dimensional image signal, dividing the wavelet-transformed image signal into blocks, and calculating a correlation in a specific direction of the block-divided image signal. Controlling a local wavelet transform, performing a local wavelet transform on a specific frequency component of the block-divided image signal according to the control signal, quantizing the local wavelet-transformed image signal, An image encoding method for encoding an image signal. 20. A two-dimensional image signal is subjected to a wavelet transform, the wavelet-transformed image signal is divided into blocks, and the block-divided image signal is subjected to a specific frequency component according to a control signal based on local property detection. Performing a local wavelet transform, quantizing the image signal subjected to the local wavelet transform, encoding the quantized image signal, dequantizing the quantized image signal, and dequantizing the dequantized image signal. On the other hand, a local wavelet inverse transform is performed on a specific frequency component in accordance with a control signal based on local property detection, an image signal in which the specific frequency component is subjected to the wavelet inverse transform is stored, and encoding is performed from the stored image signal. The image signal of the block adjacent to the target image block to be read is read out and the specific frequency of the image signal is read out. An image coding method, wherein local properties are detected by calculating correlations of components in a specific direction to control the local wavelet transform and the local wavelet inverse transform. 21. Decoding a block-divided and encoded two-dimensional image signal, dequantizing the signal of the decoded image block, and detecting a local property of the signal of the dequantized image block. Performing an inverse local wavelet transform in accordance with a control signal, storing an image signal in which the specific frequency component is inversely subjected to the wavelet transform, reading out an image signal of a block adjacent to a target image block to be decoded from the stored image signal, and executing an image processing. A local property is detected by obtaining a correlation in a specific direction of a specific frequency component of a signal to control the local inverse wavelet transform, and the specific frequency component is used to convert an image frame from an image block signal subjected to the inverse wavelet transform. Performing an inverse two-dimensional wavelet transform on the configured image frame. A featured image decoding method. 22. When a vertical correlation value of a horizontal low frequency component of an input image block is larger than a prescribed value, a vertical primary wavelet transform is performed on the horizontal low frequency component. A control signal is output, and when the correlation value in the horizontal direction of the low frequency component in the vertical direction of the input image block is larger than a predetermined value, the horizontal primary wavelet transform is performed on the low frequency component in the vertical direction. 22. The image encoding method according to claim 19, wherein the control signal is output in such a manner as to output the control signal.