JP2005020384A - Hierarchal encoding device and image decoding device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the encoding efficiency for a hierarchal encoding device which conducts encoding processing including quantization processing with dead zone at a basic hierarchy, and conducts bit plane encoding processing for a remainder image that is difference between an original image and a decoded image of the basic hierarchy at an extended hierarchy. <P>SOLUTION: A basic hierarchy encoding processing means 1 conducts encoding processing including quantization processing with dead zone for the basic hierarchy of an original image 11. An extended hierarchy encoding processing means 2 conducts bit plane encoding processing for a remainder image 14 showing difference between the original image 11 and a decoded image of the basic hierarchy. The extended hierarchy encoding processing means 2 identifies an omissible information symbol for each coefficient of the extended hierarchy with reference to a quantization value 15 located at the same position of the basic hierarchy, and omits bit plane encoding processing for the identified information symbol. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
【Technical field】
The present invention relates to an image hierarchical encoding apparatus and decoding apparatus, and more particularly to an image hierarchical encoding apparatus and decoding apparatus that perform encoding processing hierarchically in two layers of a basic hierarchy and an enhancement hierarchy with respect to image quality. Is.
[0002]
[Background]
Hierarchy that gives a hierarchical structure to an encoded signal by encoding the image into two layers of a basic layer and an extended layer with respect to image quality and the like when encoding and compressing the image from the viewpoint of information amount compression Coding techniques are known. According to this technique, it is possible to efficiently transmit and decode an image by selecting a hierarchy according to the environment at the time of decoding.
[0003]
In recent years, MPEG-4 and H.264 have been used as one of hierarchical encoding techniques for images. Examples thereof include FGS (Fine Granularity Scalability) coding technology studied in the 26L moving image coding standard. In the FGS encoding device, in order to improve scalability (decoding freedom) related to image quality, bit plane encoding processing is performed, and encoding processing is performed in order from the upper bit plane. Even if the encoded image signal is interrupted during decoding in the decoding process, an image with an image quality corresponding to the amount of information that has been decoded can be reconstructed. Therefore, the hierarchical coding technique of an image is effective when applied to the field of video streaming transmission.
[0004]
[Problems to be solved by the invention]
However, since the coding process of the enhancement layer in the conventional hierarchical coding apparatus is merely a bit-plane coding of the divided enhancement layer, the coding efficiency is low and the code is not layered. There is a problem that the image quality at the same encoding rate is very poor compared to the encoding method.
[0005]
An object of the present invention is to provide a hierarchical encoding device and a decoding device that can solve the problem of lowering of the encoding efficiency in the prior art and improve the encoding efficiency. When the encoding process is performed, the information symbol encoding process which can be omitted with reference to the information of the base layer is omitted.
[0006]
[Means for Solving the Problems]
In order to solve the above-described problem, the present invention divides an input original image into two layers of a basic layer and an extended layer, and performs encoding processing including quantization processing with a dead zone in the basic layer, In the image hierarchical encoding device, when the residual image, which is a difference between the original image and the decoded image of the basic layer, is subjected to bit-plane encoding processing, An information symbol that can be omitted is identified for each enhancement layer coefficient with reference to the quantized value in (2), and an omitted symbol specifying / encoding process omitting unit that omits the bit-plane encoding process for the identified information symbol. There is a feature in the prepared point.
[0007]
The omitted symbol specifying / encoding process omitting means specifies the dynamic range of each coefficient of the enhancement layer with reference to the quantized value at the same position in the base layer, and based on the dynamic range, determines the bit plane of the enhancement layer. It is possible to perform bit-plane encoding processing by removing binary information symbols that do not need to be encoded from the inside.
[0008]
In addition, a positive / negative information symbol that does not need to be encoded is identified with reference to both the quantized value at the same position in the base layer and the size of each coefficient in the enhancement layer, and the positive / negative information symbol is removed to remove the bit plane. An encoding process may be performed. Furthermore, it is also possible to perform bit-plane encoding processing by removing both binary information symbols and positive / negative information symbols that do not need to be encoded.
[0009]
In addition, binary information symbols may be output as they are as binary sequences without performing bit-plane encoding for one or several bit planes in the enhancement-layer bit planes. In this case, consideration is given so that the output binary sequence does not include the control code.
[0010]
Furthermore, the present invention is also characterized by a decoding apparatus that decodes an encoded signal generated by the hierarchical encoding apparatus having the above characteristics. The decoding process in the decoding device may be a process opposite to the encoding process.
[0011]
【The invention's effect】
According to the feature of the present invention, since binary information symbols and positive / negative information symbols that do not need to be encoded are removed from the bit planes of the enhancement layer and bit plane encoding processing is performed, encoding efficiency is improved. In addition, since the bit plane processing is used for the encoding processing of the enhancement layer, it has a structure that can realize high scalability with respect to the quality of the decoded image.
[0012]
In addition, in a bit plane where the occurrence of binary information symbols is random, the bit plane encoding process is not performed, and the binary information symbols are output as they are as binary sequences, so that the amount of information generated can be reduced. The increase can be suppressed. In this case, by considering that the output binary sequence does not include a control code, it is not erroneously recognized as a control code at the time of decoding, and malfunction can be prevented.
[0013]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a basic form of an image hierarchical coding apparatus according to the present invention. The hierarchical encoding apparatus includes a base layer encoding processing unit 1 that encodes a base layer of an original image 11, an extension layer encoding processing unit 2 that encodes an extension layer, and a base layer encoding processing unit 1. A base layer decoding processing means 3 for decoding the base layer encoded signal to be output, and a residual image 14 which is a difference between the original image 11 and the base layer decoded image 13 output from the base layer decoding processing means 3 And an adder 4 for outputting.
[0014]
The base layer encoding processing means 1 outputs the base layer quantized value 15 in addition to the base layer encoded signal 12, and gives the quantized value 15 to the extension layer encoding processing means 2. The enhancement layer coding processing means 2 outputs a coded signal 16 of the enhancement layer.
[0015]
The outline of the operation of the hierarchical encoding apparatus is as follows. The input original image 11 is divided into two and input to the base layer encoding processing means 1 and the adder 4 respectively. The base layer encoding processing means 1 encodes the base layer of the original image 11 and outputs a base layer encoded signal 12 and also outputs a base layer quantized value 15. The base layer decoding processing means 3 decodes the base layer encoded signal 12 and outputs a base layer decoded image 13, which is input to the adder 4.
[0016]
The output of the adder 4, that is, the residual image 14, which is the difference between the original image 11 and the base layer decoded image 13, is to be encoded by the enhancement layer encoding processing means 2. The enhancement layer encoding processing unit 2 refers to the quantization value 15 obtained during the encoding process in the base layer encoding processing unit 1 and specifies information symbols that can be omitted for each coefficient of the extension layer, The specified information symbol is omitted, encoding processing is performed in bit plane units, and an enhancement layer encoded signal 16 is output.
[0017]
FIG. 2 is a block diagram showing the configuration of the base layer encoding processing means 1, and it is assumed that quantization processing with a dead zone is performed in the base layer. In the figure, an original image 11 is input to a quantization processing means with dead zone 21 and quantized, and a quantized value is output as a quantized value 15 of a base layer, and the quantized value 15 is a run-length code. Encoded by the encoding process or the like and output as the encoded signal 12 of the base layer.
[0018]
FIG. 3 shows an example of the characteristics of the quantization process with a dead zone in comparison with the characteristics of the quantization process without a dead zone. FIG. 4A shows the characteristics of the quantization processing without dead zone, and FIG. 4B shows the characteristics of the quantization processing with dead zone. Here, it is assumed that the quantization step width is set to 2Δ.
[0019]
The characteristic (a) of the quantization process without dead zone has a uniform quantization range of 2Δ for all quantization representative values, but the characteristic (b) of the quantization process with dead zone is The quantization range at the representative value 0 has a range (4Δ) wider than 2Δ, and the quantization ranges of the other quantization representative values are all linear quantization characteristics that are constant at the quantization step width 2Δ.
[0020]
When the base layer is quantized using the quantization process with a dead zone, the range of values of residual coefficients that can be generated in the extended layer differs depending on whether the quantized value of the base layer is 0 or non-zero. The present invention pays attention to this characteristic, and after removing binary information symbols and positive / negative information symbols that do not need to be encoded from the bit planes of the enhancement layer, encoding efficiency is improved by performing bit plane encoding processing. It is an improvement.
[0021]
Details thereof will be described below. Here, in order to simplify the explanation, H.C. It is assumed that the linear quantization processing with dead zones is the same as that specified in the quantization processing for AC coefficients of the H.263 intra block, but the same is realized with quantization processing with other dead zones. can do.
[0022]
The quantization process with a dead zone is expressed by the following equation.
｜ LEVEL ｜ = Floor (| COF | / 2Δ)
LEVEL = Sign (COF) × | LEVEL |
Here, COF is a coefficient value of the original image, LEVEL is a quantization value of the base layer, 2Δ is a quantization step width, and Floor (x) indicates a maximum integer value not exceeding x. Sign (x) indicates the sign of x and is defined below.
If x ≧ 0, Sign (x) = + 1
If x <0, Sign (x) = − 1
[0023]
The inverse quantization process with dead zone is expressed by the following equation.
When LEVEL = 0, | COF '| = 0
When LEVEL ≠ 0, Δ is an odd number, | COF ′ | = 2Δ × | LEVEL | + Δ
When LEVEL ≠ 0, Δ is an even number, | COF ′ | = 2Δ × | LEVEL | + Δ−1
COF ′ = Sign (LEVEL) × | COF ′ |
Here, COF ′ is a coefficient value of the decoded image of the base layer.
[0024]
As is clear from the above equation, when the quantization process with dead zone and the inverse quantization process are used for the base layer encoding process and the base layer decoding process, the range that the residual coefficient of the enhancement layer can take is that of the base layer. It differs depending on whether the quantized value is 0 or non-zero.
[0025]
Residual coefficient values that can occur in the extended hierarchy can be classified as follows.
When LEVEL = 0, -2Δ <RESIDUE <+ 2Δ
When LEVEL> 0, Δ is an odd number, −Δ ≦ RESIDUE <+ Δ
When LEVEL <0, Δ is an odd number, −Δ <RESIDUE ≦ + Δ
When LEVEL> 0, Δ is an even number, −Δ + 1 ≦ RESIDUE <+ Δ + 1
When LEVEL <0, Δ is an even number, −Δ−1 <RESIDUE ≦ + Δ−1
Here, RESIDUE is a residual coefficient.
[0026]
Therefore, it can be seen that the dynamic range of the residual coefficient of the enhancement layer when the quantization value of the base layer is non-zero is about ½ of the dynamic range when the quantization value of the base layer is 0. . The difference in dynamic range is that the residual coefficient of the enhancement layer when the quantization value of the base layer is non-zero is greater than the residual coefficient of the enhancement layer when the quantization value of the base layer is 0. This means that it can be expressed by binary information symbols that are always one bit fewer.
[0027]
For example, when the quantization step width 2Δ = 20, the residual coefficient of the enhancement layer is classified as follows depending on whether the quantization value of the base layer is 0 or non-zero.
When LEVEL = 0, −20 <RESIDUE <+20
When LEVEL> 0, −9 ≦ RESIDUE <+11
When LEVEL <0, −11 <RESIDUE ≦ + 9
[0028]
In this case, the magnitude of the residual coefficient of the enhancement layer when the quantization value of the base layer is 0 is expressed by 5 bits, but when the quantization value of the base layer is non-zero, it is 1 bit from that It can be represented by a small number of 4 bits.
[0029]
However, in the conventional enhancement layer coding process, the maximum value of the residual coefficient of the enhancement layer to be encoded (in this example, the maximum value 2Δ−1 = 19 when the quantization value of the base layer is 0) Since bit plane encoding processing is performed by expressing the bit plane with the number of bits matched to (), the residual coefficient when the quantization value of the base layer is non-zero is always encoded by one bit extra. It was.
[0030]
FIG. 4 is an explanatory diagram of the flow of the enhancement layer bit-plane encoding process employed in the conventional FGS encoding technique. However, here, the quantization step width 2Δ = 20 is set, and the quantization process is H.264. It is assumed that it is for an H.263 inter block. H. In the quantization processing for the inter (Inter) block of H.263, only the calculation formula for obtaining the quantized value is different from that for the intra (intra) block.
LEVEL = 0, −25 <RESIDUE <+25
LEVEL> 0, -4 ≦ RESIDUE <+16
LEVEL <0, −16 <RESIDUE ≦ + 4
It becomes.
[0031]
In the following, H.C. A case of quantization processing for an H.263 inter block will be described as an example. In the FGS coding technique which is one of the moving picture hierarchical coding schemes, the residual coefficient RESIDUE in the DCT block (FIG. 4A) of the residual picture of the enhancement hierarchy is rearranged into a primary series by zigzag scanning ( (B)), and further converted into binary representation ((c)), then binary information symbols of each bit plane ((d), (e)) are binary zero-run-length encoded. Encode by processing.
[0032]
On the other hand, the present invention skips without performing the encoding process of these extra encoded binary information symbols in the most significant bit plane of the residual coefficient of the enhancement layer, The generated encoded information is reduced by reducing the binary information symbols.
[0033]
FIG. 5 is a block diagram showing a configuration of the enhancement layer coding processing means 2. The residual image 14 from the adder 4 (FIG. 1) is input to the unnecessary binary information symbol removing means 53, and the base layer quantized value 15 from the base layer encoding processing means 1 (FIG. 1) is used to specify the dynamic range. Input to means 54. The dynamic range specifying unit 54 specifies the dynamic range of the residual coefficient RESIDUE with reference to whether the quantization value of the base layer is 0 or non-zero.
[0034]
The unnecessary binary information symbol removing unit 53 removes the binary information symbol that can be omitted from the enhancement layer based on the dynamic range 51 specified by the dynamic range specifying unit 54. The difference image signal 52 from which the binary information symbols that can be omitted without the need for bit-plane encoding are removed is encoded by the removal symbol skip type bit-plane encoding processing means 55.
[0035]
FIG. 6 is an explanatory diagram of the flow of the enhancement layer bit-plane encoding process according to FIG. The residual coefficient RESIDUE in the DCT block of the enhancement layer residual image is rearranged into a primary series by zigzag scanning, and further converted into a binary representation (FIG. 6A). Here, referring to the quantized value LEVEL of the base layer ((c) in the figure), if LEVEL is non-zero, the bit plane encoding processing of the binary information symbol at the top of the residual coefficient of the enhancement layer is performed. Skip without doing. In FIG. 6B, a binary information symbol which can be omitted in the MSB bit plane is indicated by a symbol S.
[0036]
Although details of the decoding process will be described later, even if the binary information symbols of the residual signal of the enhancement layer are partially omitted at the time of decoding, by referring to the basic layer, Value information symbols can be supplemented. As a result, the number of binary information symbols to be subjected to bit-plane encoding is reduced, so that the amount of encoded information generated in the enhancement layer can be reduced.
[0037]
In the above, the embodiment has been described in which binary information symbols that do not need to be encoded are omitted from the bit planes of the enhancement layer, but the positive and negative information symbols that do not need to be encoded are used alone or the two above-described two information symbols. It can be omitted together with the omission of the value information symbol. Hereinafter, this embodiment will be described.
[0038]
H. The quantization process for the H.263 inter block is described in the above-mentioned H.264 standard. Only the calculation formula for obtaining the quantization value is different from the intra-block of H.263 as follows.
| LEVEL | = Floor ((| COF | −Δ / 2) / 2Δ)
[0039]
Therefore, depending on whether the quantization value of the base layer is 0 or non-zero, the possible range of the residual coefficient of the enhancement layer is a case where the quantization value of the base layer is 0 or non-zero And different. In this case, the residual coefficient values that can occur in the enhancement layer can be classified as follows.
When LEVEL = 0 and Δ is an odd number, −5Δ / 2 <RESIDUE <+ 5Δ / 2
When LEVEL> 0, Δ is an odd number, −Δ / 2 ≦ RESIDUE <+ 3Δ / 2
When LEVEL <0, Δ is an odd number, −3Δ / 2 <RESIDUE ≦ + Δ / 2
When LEVEL = 0 and Δ is an even number, −5Δ / 2 <RESIDUE <+ 5Δ / 2
When LEVEL> 0, Δ is an even number, −Δ / 2 + 1 ≦ RESIDUE <+ 3Δ / 2 + 1
When LEVEL <0, Δ is an even number, −3Δ / 2-1 <RESIDUE ≦ + Δ / 2-1
[0040]
Therefore, the range in which positive and negative are determined by the positive and negative of the quantization value of the base layer is as follows.
When LEVEL> 0, Δ is an odd number, if | RESIDUE |> Δ / 2, then Sign (RESIDUE) = + 1
When LEVEL <0, Δ is an odd number, if | RESIDUE |> Δ / 2, then Sign (RESIDUE) = − 1.
When LEVEL> 0, Δ is an even number, if | RESIDUE |> Δ / 2-1, it is always Sign (RESIDUE) = + 1.
When LEVEL <0, Δ is an even number, if | RESIDUE |> Δ / 2−1, then Sign (RESIDUE) = − 1.
[0041]
However, in consideration of the encoding process of the upper bit plane, the range in which positive / negative is uniquely determined by the positive / negative of the quantization value of the base layer is limited as follows. That is, the quantization value of the base layer is not 0, and the residual coefficient magnitude of the enhancement layer is 2 ⁿ (N is 2 when Δ is an even number) ⁿ > Δ / 2-1, when Δ is an odd number 2 ⁿ (Minimum value such that> Δ / 2), the sign of the residual coefficient of the enhancement layer is equal to the sign of the quantization value of the base layer.
[0042]
If this characteristic is used, it is possible to specify the sign of the residual signal of the enhancement layer by referring to the base layer even when there is no positive / negative information symbol of the residual signal of the enhancement layer at the time of decoding. Therefore, when the bit plane coding of the residual coefficient of the enhancement layer is advanced, the positive / negative information symbols can be skipped without being coded, and thus the amount of coded information generated can be reduced.
[0043]
FIG. 7 is a block diagram showing a configuration of an enhancement layer encoding processing unit that skips without encoding positive / negative information symbols. The residual image 14 from the adder 4 (FIG. 1) is input to an unnecessary positive / negative information symbol removing unit 73, and the base layer quantization value 15 from the basic layer encoding processing unit 1 (FIG. 1) is an unnecessary positive / negative information symbol. Input to the specifying means 74.
[0044]
As described above, the unnecessary positive / negative information symbol specifying unit 74 has a quantization value of 0 in the base layer and a residual coefficient magnitude of 2 in the extension layer. ⁿ (N is 2 when Δ is an even number) ⁿ > Δ / 2-1, when Δ is an odd number 2 ⁿ (Minimum value such that> Δ / 2), the positive / negative information symbol of the coefficient can be removed, and the position information 71 of the coefficient that does not require the positive / negative information symbol is output.
[0045]
Positive / negative information symbols that can be removed by the unnecessary positive / negative information symbol specifying means 73 are removed by the unnecessary positive / negative information symbol removing means 73. The difference image signal 72 from which unnecessary positive / negative information symbols have been removed is encoded by the removal symbol skip type bit plane encoding processing means 75, and the encoded signal 16 of the enhancement layer is output.
[0046]
FIG. 8 is an explanatory diagram of the flow of the enhancement layer bit-plane encoding process according to FIG. FIG. 4A shows a specific numerical example of the range of the residual coefficient RESIDUE when the quantization step width is 2Δ (= 20, Δ is an even number). In this example,
LEVEL = 0, −25 <RESIDUE <+25
LEVEL> 0, -4 ≦ RESIDUE <+16
LEVEL <0, −16 <RESIDUE ≦ + 4
It becomes.
[0047]
The residual coefficients RESIDUE in the DCT block of the enhancement layer residual image are rearranged into a primary series by zigzag scanning, and further converted into a binary representation (FIG. 8B). Here, the quantized value LEVEL of the base layer is referred to ((c) in the same figure), LEVEL is non-zero, and the magnitude of the residual layer residual coefficient is 2 ³ (2 ³ In the case of> 4 = Δ / 2-1) or more, the sign of the residual coefficient is equal to the sign of the quantization value of the base layer, so that it is skipped without performing the bit plane coding process of the sign information symbol. In FIG. 6C, a positive / negative information symbol which can be omitted in the Sign bit plane is indicated by a symbol S. As a result, the number of positive / negative information symbols to be subjected to bit plane encoding is reduced, so that the amount of encoded information generated in the enhancement layer can be reduced.
[0048]
In the present invention, as described below, the amount of encoded information can be further effectively reduced by performing bit-plane encoding considering the signal distribution of the residual coefficient of the enhancement layer. In the least significant bit plane of the residual coefficient of the enhancement layer, the appearance probability of the binary information symbol is usually random. In addition, depending on the type of the input original image, the appearance probability of the binary information symbol may be random not only in the lowest bit plane but also in some higher bit planes.
[0049]
In this way, in the bit plane where the appearance probability of the binary information symbol is random, the compression effect by encoding cannot be obtained, and when a code word is created by performing bit plane encoding processing like other bit planes, On the contrary, a larger amount of encoded information than that of the original binary information symbol is generated.
[0050]
Therefore, the binary information symbol is encoded as it is without encoding the lowest bit plane, and in some cases the higher bit planes, by the same bit plane encoding process as other bit planes. It is effective to output as a binary series.
[0051]
In this case, in each bit plane, whether to perform bit plane encoding or not to output a binary information symbol as it is as an encoded binary sequence is determined before starting the bit plane encoding process. This can be done by measuring the appearance probability of the binary information symbols 0 and 1 every time. For example, if the appearance probabilities of binary information symbols 0 and 1 in the bit plane are close to ½, the binary information symbol generated in the bit plane is considered to be random, and the encoding process is performed as it is. It can be considered as a target.
[0052]
FIG. 9 is a block diagram illustrating a configuration of an encoding process that takes into account the appearance probability of a binary information symbol. For the bit plane 91 in which the binary information symbol appearance probability is random in the residual image of the enhancement layer, the binary information symbol is not encoded by the same bit plane encoding process as other bit planes. Are directly output as an encoded binary sequence, and a binary unencoded signal sequence 92 is created.
[0053]
However, there is a possibility that the same binary sequence as the control code for the decoding process is generated in the binary uncoded signal sequence 92, and a malfunction is likely to occur due to this binary sequence during the decoding process. In order to prevent this malfunction, control code duplication discharge avoidance processing is performed so that the control code is not included in the encoded binary sequence in the binary unencoded signal sequence 92, and the encoded signal 93 of the enhancement layer Create
[0054]
As a specific example, the control code defined in MPEG-4 consists of a 32-bit binary sequence, in which 23 consecutive “0” s are described in the first half, and the type of control code is shown in the second half. A binary sequence of bits is described. In MPEG-4 having such a control code, if the binary information symbol is output as it is as a code word and 23 symbols '0' are output continuously, the MPEG-4 control code and Since they overlap, there is a high possibility of malfunction during the decoding process.
[0055]
In order to prevent this, the control code duplication discharge avoidance process is performed. In this process, for example, the number of consecutive symbols “0” is not output while 23 symbols “0” are being output as they are. When the number reaches 22, the output processing is performed so that the pause symbol “1” is inserted immediately after that. By this control code duplication discharge avoidance process, there is no possibility that 23 or more symbols '0' appear continuously, and the binary information symbol is encoded as it is without discharging the same binary sequence as the control code. It becomes possible to output as a series.
[0056]
For the bit planes 94 excluding the bit plane 91 where the appearance probability of the binary information symbol is random, a bit plane encoding process is performed and an encoded signal 95 is output.
[0057]
FIG. 10 is an explanatory diagram of the flow of the enhancement layer encoding process according to FIG. Residual coefficients RESIDUE in the DCT block of the residual image in the enhancement layer are rearranged into a primary series by zigzag scanning (FIG. (A)), and further converted into a binary representation (FIG. (B)). Usually, as shown in (c) of the figure, the appearance probability of the binary information symbol becomes random as the lower bit plane of the residual coefficient of the enhancement layer. Therefore, in this example, the least significant bit (LSB) plane in which the appearance probability of binary information is random is output as a codeword as it is. At this time, processing for avoiding the discharge of the same binary series as the control code is added.
[0058]
Next, a decoding apparatus for decoding an encoded signal that has been subjected to hierarchical encoding processing as described above will be described. The decoding apparatus basically reconstructs a decoded image from encoded signals of the basic layer and the enhancement layer by performing a process reverse to the encoding process.
[0059]
FIG. 11 is a block diagram showing the basic configuration of the decoding apparatus of the present invention. This decoding apparatus includes base layer decoding processing means 114, enhancement layer decoding processing means 115, and adder 116.
[0060]
The base layer decoding processing means 114 decodes the base layer encoded signal 12 to output a base layer decoded image 13 and also outputs a base layer quantized value 111. The enhancement layer decoding processing means 115 receives the enhancement layer encoded signal 16 and the base layer quantization value 111 as inputs, and outputs an enhancement layer residual decoded image 112. When outputting this residual decoded signal, the binary processing is the reverse of the encoding process, that is, with reference to the quantized value 111 of the base layer, and the omitted binary at the same position as the position where the quantized value 111 is 0. Decode after embedding information symbols. Note that the omitted binary information symbols are embedded for the convenience of decoding in accordance with the number of bits.
[0061]
The adder 116 adds the decoded image 13 of the base layer and the residual decoded image 112 of the enhancement layer to reconstruct the original image 113. Note that an image at the base layer level can be output using only the decoded image 13 of the base layer.
[0062]
FIG. 12 is a block diagram showing the configuration of the enhancement layer decoding processing means 115, which performs processing reverse to the encoding processing of FIG. The enhancement layer encoded signal 16 and the base layer quantization value 111 are respectively input to the removal symbol skip type bit plane decoding processing means 123 and the dynamic range specifying means 124. The dynamic range specifying unit 124 specifies the dynamic range of the residual coefficient RESIDUE with reference to whether the quantization value 111 of the base layer is 0 or non-zero.
[0063]
The removal symbol skip type bit plane decoding processing means 123 refers to the dynamic range 122 specified by the dynamic range specifying means 124, skips binary information symbols removed in the enhancement layer (skip decoding), and performs bit plane decoding. Process. The binary information symbol embedding unit 125 embeds the binary information symbol 0 omitted at the time of encoding, and outputs a decoded residual image 112 of the enhancement layer.
[0064]
FIG. 13 is also a block diagram showing the configuration of the enhancement layer decoding processing means 115, which performs processing reverse to the encoding processing of FIG. The enhancement layer encoded signal 16 and the base layer quantization value 111 are respectively input to the removal symbol skip type bit plane decoding processing means 134 and the positive / negative information symbol specifying means 135. The positive / negative information symbol specifying means 135 refers to the quantized value 111 of the base layer and the magnitude of the residual layer residual coefficient, and position information 132 of the coefficient in which the positive / negative information symbol is unnecessary, and its positive / negative information 133 (base layer). The same positive / negative information).
[0065]
The removal symbol skip type bit plane decoding processing means 134 refers to the position information 132 of the coefficient in which the positive / negative information symbol is unnecessary, skips the positive / negative information symbol removed in the enhancement layer (skip decoding), and the bit plane. Perform decryption. The positive / negative information symbol embedding unit 136 embeds the positive / negative information symbol omitted at the time of encoding with the positive / negative information 133 and outputs the decoded residual image 112 of the enhancement layer.
[0066]
FIG. 14 is a block diagram showing the configuration of the enhancement layer decoding processing means when the appearance probability of the binary information symbol is taken into account, and performs processing reverse to the encoding processing of FIG. The enhancement layer coded signal (non-bitplane coding) 93 is converted into the original binary uncoded signal sequence 141 by a process reverse to the control code duplication discharge avoiding process of FIG. 9, and this is directly used as a binary information symbol. It is decoded to become a specific bit plane 142 of the decoded residual image.
[0067]
In the case of the specific example described with reference to FIG. 9, if 22 symbols “0” continue, it can be considered that a pause symbol “1” is inserted next, so that the pause symbol “ 1 ′ is skipped, and the remaining encoded binary sequences are sequentially arranged in the target bit plane. Also, the enhancement layer encoded signal 95 excluding the enhancement layer encoded signal (non-bitplane encoding) 93 is subjected to bit plane decoding processing to become a bit plane excluding the residual image signal 142.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a basic form of an image hierarchical coding apparatus according to the present invention.
FIG. 2 is a block diagram showing a configuration of base layer encoding processing means.
FIG. 3 is a characteristic diagram of quantization processing without dead zone and with dead zone.
FIG. 4 is an explanatory diagram of a flow of an enhancement layer bit-plane encoding process employed in a conventional FGS encoding technique.
FIG. 5 is a block diagram showing a configuration of enhancement layer encoding processing means.
6 is an explanatory diagram of a flow of an enhancement layer bit plane encoding process according to FIG. 5. FIG.
FIG. 7 is a block diagram showing another configuration of the enhancement layer encoding processing means.
FIG. 8 is an explanatory diagram of a flow of an enhancement layer bit plane encoding process according to FIG. 7;
FIG. 9 is a block diagram showing a configuration of an encoding process in consideration of the appearance probability of a binary information symbol.
10 is an explanatory diagram of a flow of an enhancement layer encoding process according to FIG. 9. FIG.
FIG. 11 is a block diagram showing a basic configuration of a decoding apparatus according to the present invention.
FIG. 12 is a block diagram showing a configuration of enhancement layer decoding processing means.
FIG. 13 is a block diagram showing another configuration of the enhancement layer decoding processing means.
FIG. 14 is a block diagram illustrating a configuration of a decoding process in consideration of the appearance probability of a binary information symbol.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Base layer encoding processing means, 2 ... Extension layer encoding processing means, 3,114 ... Base layer decoding processing means, 21 ... Quantization processing means with a dead zone, 53 ... Unnecessary binary information removing means, 54, 124 ... dynamic range specifying means, 55, 75 ... removal symbol skip type bit plane encoding processing means, 73 ... unnecessary positive / negative information symbol removing means, 74 ... Unnecessary positive / negative information symbol specifying means, 114... Enhancement layer decoding processing means, 123 and 134... Removal symbol skip type bit plane decoding processing means, 125... Binary information symbol embedding means, 135. Information symbol specifying means, 136... Positive / negative information symbol embedding means, 74... Bit plane encoding unit

Claims (8)

The input original image is divided into two layers, a basic layer and an extended layer. The basic layer performs a coding process including a quantization process with a dead zone, and the extended layer is a difference between the original image and the decoded image of the basic layer. In a hierarchical image coding apparatus that performs a bit-plane coding process on a residual image,
When performing the encoding process of the enhancement layer, an optional information symbol is identified for each enhancement layer coefficient with reference to the quantization value at the same position in the base layer, and the identified information symbol is a bit plane. An image hierarchical encoding apparatus comprising: an abbreviated symbol specifying / encoding process omitting unit that omits an encoding process. The abbreviated symbol identification / encoding processing omission unit includes a dynamic range identification unit that identifies a dynamic range of each coefficient in the enhancement layer with reference to a quantization value at the same position in the base layer, and a dynamic range identification unit Binary information symbol removing means for removing unnecessary information symbols to be encoded from the bit plane of the enhancement layer with reference to the specified dynamic range, and the binary information symbol removed by the binary information symbol removing means. 2. The image hierarchical coding apparatus according to claim 1, further comprising bit plane coding processing means for performing bit plane coding processing by skipping value information symbols. The abbreviated symbol identification / encoding processing omission means encodes positive / negative information symbols of each coefficient in the extended layer with reference to both the quantized value at the same position in the basic layer and the size of each coefficient in the extended layer. Positive / negative information symbol specifying means for determining the necessity to perform, and removing the positive / negative information symbols that need not be encoded from the bit plane of the enhancement layer with reference to the necessity determined by the positive / negative information symbol specifying means 2. The positive / negative information symbol removing means and a bit plane coding processing means for performing a bit plane coding process by skipping the positive / negative information symbols removed by the positive / negative information symbol removing means. Image hierarchical encoding device. A binary sequence output means for outputting a binary information symbol as it is as a binary sequence without performing bit-plane encoding for one or several bit planes in the bit plane of the enhancement layer; and the binary 4. The image hierarchy according to claim 1, further comprising codeword output means for outputting a codeword so that the binary series output from the series output means does not include a control code. Coding device. Decoding by the base layer decoding processing means for decoding the base layer encoded signal, the enhancement layer decoding processing means for decoding the enhancement layer encoded signal in bit plane units, and decoding by the base layer decoding processing means and the enhancement layer decoding processing means An image decoding device for decoding an encoded signal generated by the image hierarchical encoding device according to claim 1,
When performing the decoding process of the enhancement layer, the information symbol omitted for each coefficient of the enhancement layer is identified by referring to the quantization value at the same position in the base layer, and the appropriate information symbol is assigned to the information symbol position. An image decoding apparatus comprising bit plane decoding processing means for embedding and performing bit plane decoding processing. The bit plane decoding processing means includes a dynamic range specifying means for specifying a dynamic range of each coefficient of the enhancement layer with reference to a quantized value at the same position in the base layer, and a dynamic range specified by the dynamic range specifying means. Bit plane decoding processing means for performing bit plane decoding processing by skipping binary information symbols removed in the enhancement layer with reference to the range, and embedding means for embedding binary information symbols removed in the enhancement layer The image decoding apparatus according to claim 5, further comprising: Whether the bit plane decoding processing means omits encoding of positive / negative information symbols of each coefficient of the enhancement layer with reference to both the quantized value at the same position in the base layer and the size of each coefficient of the enhancement layer Positive / negative information symbol specifying means for specifying whether or not and its positive / negative, and bit plane decoding processing means for performing bit plane decoding processing by skipping positive / negative information symbols specified by the positive / negative information symbol specifying means and removed in the enhancement layer The image decoding apparatus according to claim 5, further comprising an embedding unit that embeds the positive / negative information symbol removed in the enhancement hierarchy. Binary information symbols of bit planes that are output as binary sequences as they are without being subjected to bit plane encoding during the encoding process are input and processed so as not to include control codes. 8. The image decoding apparatus according to claim 5, further comprising means for outputting binary information symbols and arranging them at corresponding bit plane positions.

Images