DE69738381T2 - Device for generating a bit stream - Google Patents

Description

TECHNICAL AREA

The The present invention relates to a device for generating a bitstream.

STATE OF THE ART

A system based on MPEG-4 (Moving Picture Experts Group Phase-4) currently on the way to standardization in ISO / IEC JTC11 / SC29 / WG11 is different from a system based on the ITU-T Recommendation H.263 with respect to the header information (an information signal for decoding) to be added to a coded bit stream forming a transmitted signal.

1 (a) is a diagram showing the structure of a coded H.263 bitstream 201 based on the H.263 standard shows in the header information 211 introduced by multiplexing together with macroblock data 225 consisting of coded image data coded according to the H.263 coding scheme. 1 (b) Figure 4 is a diagram illustrating the structure of a coded MPEG-4 bitstream 202 shows, in the header information 212 introduced by multiplexing together with macroblock data 239 consisting of coded picture data coded according to the MPEG-4 coding scheme. As shown in these figures, they have different coded bitstream structures. In particular, H.263 does not contain intent information about VO (Video Object), VOL (Video Object Layer), VOP (Video Object Plane) and the like required for MPEG-4 decoding. Accordingly, to perform image communications based on the two schemes, separate image decoding devices and image encoding devices are needed.

Here it is not always necessary for a GOB startup code 223 and GOB header information 224 in the encoded H.263 bitstream 201 and a resync instruction code 237 ' and resynchronization information 238 in the MPEG-4 encoded bitstream 202 be introduced but then introduced when they are needed.

In these structures, the conventionally encoded bitstreams present a problem in that an MPEG-4 compatible image decoding apparatus, for example, the H.263 encoded bitstream 201 which has not been able to decode according to the H.263 standard.

Farther must match the coded bitstreams accordingly to decode the MPEG-4 standard and the H.263 standard, an image decoding device have two decoders based on the two schemes, which is a problem regarding the complexity of the device represents.

JP-A-9139937 already discloses a moving picture stream converting apparatus constituted by a demultiplexer, a packetizer and a multiplexer. The demultiplexer receives an MPEG-1 system stream containing a stream of encoded video data and a stream of encoded audio data, and separates elementary stream (ES) from the video and audio data, respectively. A packetized elementary stream PES of MPEG 2 is formed by the packetizer each of the video and audio elementary streams separated by the demultiplexer. The multiplexer separates the packetized video and audio elementary streams into transport packets each having a fixed amount (188 bytes), and thereafter multiplexes with the transport packets, thereby converting them into a transport stream (hereinafter referred to as "TS") of MPEG 2. The MPEG-1 system stream as a conversion source is constituted by a plurality of packs in which a pack obtained by combining a plurality of packs is set as one unit. A header pack is formed by a pack header, a header and several packages. In each case the second and subsequent packs are formed by a pack header and several packages. The package is formed by an ES header and an ES payload. A packet start code, a stream ID indicating the type of video / audio and a channel number, a packet length of the ES payload, time management information for playback, and time management information for decoding were stored as parameters in the elementary stream header. Encoded video or audio data was stored in the ES payload. Each packet of the PES of MPEG 2 is formed by a PES header and a PES payload. A packet start code, a stream ID indicating the type of video / audio and a channel number, a packet length for the PES payload, time management information for a playback output, and time management information for decoding have been stored in the PES header. Encoded video or audio data was stored in the PES payload.

The The present invention has been made to solve the aforementioned problems to solve. It is therefore an object of the present invention to provide a conversion device for one coded bit stream for converting the H.263 coded bit stream into the To provide MPEG-4 encoded bitstream for carrying out communications, all of these devices have a simple structure.

DISCLOSURE OF THE INVENTION

According to the present The invention provides a device for generating a bit stream, which comprises: a header information multiplexing device for multiplexing a first coded bit stream stored in the H.263 coding scheme containing the first header information the H.263 coding scheme, with the second header information of the MPEG-4 encoding scheme before the first intent information, to ensure compatibility with the MPEG-4 encoded bitstream encoded in MPEG-4 encoding scheme, wherein the header information multiplexing device is the coded image data with the video object start code and the video object identification number of the MPEG-4 encoding scheme as the second header information for Ensuring compatibility is multiplexed with the MPEG-4 encoded bit stream.

BRIEF DESCRIPTION OF THE DRAWINGS

1 Fig. 15 is a diagram showing a structure of a conventional H.263 coded bit stream and a structure of an MPEG-4 coded bit stream;

2 Fig. 12 is a diagram showing structures of a coded bit stream received by the image decoding apparatus according to an embodiment 1 according to the present invention;

3 Fig. 10 is a block diagram showing a configuration of the image decoding apparatus according to Embodiment 1 according to the present invention;

4 Fig. 10 is a block diagram showing a configuration of the variable syntax / decoder in Embodiment 1 according to the present invention;

5 Fig. 10 is a block diagram showing a configuration of the header information analyzing apparatus in the embodiment 1 according to the present invention;

6 Fig. 10 is a block diagram showing a configuration of the H.263 picture header information analysis apparatus according to Embodiment 1 according to the present invention;

7 Fig. 12 is a block diagram showing a configuration of the H.263 picture header information decoder in the embodiment 1 according to the present invention;

8th Fig. 10 is a block diagram showing a configuration of the H.263 GOB header information analyzing apparatus in the embodiment 1 according to the present invention;

9 Fig. 16 is a diagram illustrating a GOB;

10 Fig. 10 is a block diagram showing a configuration of the GOB header information decoder in the embodiment 1 according to the present invention;

11 Fig. 16 is a diagram showing a layer structure of H.263 macroblock data;

12 Fig. 16 is a block diagram showing a configuration of the macroblock layer parser in Embodiment 1 according to the present invention;

13 Fig. 16 is a block diagram showing a configuration of the block data decoder in the embodiment 1 according to the present invention;

14 Fig. 10 is a diagram illustrating the calculation of a prediction vector;

15 Fig. 12 is a block diagram showing a configuration of the structure decoder in the embodiment 1 according to the present invention;

16 Fig. 12 is a block diagram showing a configuration of the inverse quantizer in the embodiment according to the present invention;

17 Fig. 10 is a block diagram showing a configuration of a picture coding apparatus in Embodiments 2 and 4 according to the present invention;

18 Fig. 15 is a diagram illustrating a relationship between an H.263 encoder and an MPEG-4 decoder in Embodiments 2 and 4 according to the present invention;

19 Fig. 12 is a diagram showing the content of an MPEG-4 compatible H.263 coded bit stream in an embodiment 3 according to the present invention;

20 Fig. 10 is a block diagram showing a configuration of a header information analyzing apparatus in the embodiment 3 according to the present invention;

21 Fig. 10 is a diagram showing an image communication system in an embodiment 5 according to the present invention;

22 Fig. 12 is a diagram showing an image communication system in an embodiment 6 according to the present invention;

23 Fig. 10 is a block diagram showing a configuration of a header information analyzing apparatus in an embodiment 7 according to the present invention;

24 Fig. 12 is a diagram illustrating the beginning and the end of a coded bit stream in the embodiment 7 according to the present invention;

25 Fig. 10 is a block diagram showing a coded bit stream converting apparatus in an embodiment 8 according to the present invention; and

26 Fig. 10 is a diagram showing a structure of GOB header information and a structure of resynchronization information.

BEST MODE FOR CARRYING OUT THE INVENTION

The The invention will now be described in detail with reference to the accompanying drawings described.

Embodiment 1

2 FIG. 15 is a diagram showing structures of a coded bit stream received from an image decoding apparatus in an embodiment 1, wherein FIG 2 (a) an MPEG-4 compatible H.263 encoded bitstream 203 shows, and 2 B) an MPEG-4 encoded bitstream 204 shows. The MPEG-4 compatible H.263 encoded bitstream 203 to 2 (a) contains in addition to the conventional H.263 coded bitstream 201 , as in 1 (a) shown is a VO start code 231 , a VO identification number 232 , a VOL start code 233 and H.263-compatible identification information 226 , The MPEG-4 encoded bitstream 204 to 2 B) contains in addition to the conventional MPEG-4 encoded bitstream 202 to 1 (b) H.263-compatible identification information 226 , The MPEG-4 compatible H.263 encoded bitstream 203 added H.263-compatible identification information 226 are distinguishable from the MPEG-4 encoded bitstream 204 because one of the H.263-compatible identification information is located at "0" and the other information at "1".

3 FIG. 10 is a block diagram showing a configuration of an image decoding apparatus for decoding a VO (Video Object) in Embodiment 1. FIG. In 3 denotes the reference number 1 a received coded bit stream; and 2 denotes a parser / variable length decoder included in the coded bit stream 1 syntax parses (a multiplexed video signal) and geometry coded data 3 , structure-coded data 6 and structural motion data 7 outputs. The reference number 4 denotes a geometry decoder for obtaining decoded geometry data 5 by decoding the geometry coded data 3 ; 8th denotes a motion compensator for performing motion compensation depending on the texture motion data 7 to prevent structure data 9 to obtain; and 10 denotes a structure decoder for performing decoding depending on the structure-coded data 6 and the prediction structure data 9 to decoded structure data 11 to obtain.

When next the way of working is described.

This is mainly the decoding process of the MPEG-4 compatible H.263 encoded bitstream 203 who in 2 (a) is shown, which is an object of the present invention described. In other words, a case is described in which shapes of individual VOPs are rectangular, that is, no bit stream contains geometry-coded data, and the texture data or information about the motion is coded on a macroblock basis.

The basic operation for decoding the in 2 B) shown MPEG-4 decoded bitstream 204 is the same as the conventional operation.

First, the parse / variable-length decoder translates 2 the input coded bitstream 1 from a binary bitstream into understandable data. Thus, the parsing / variable-length decoder enables 2 in that the MPEG-4 compatible H.263 encoded bitstream 203 is decoded. The motion compensator 8th performs motion compensation depending on the syntax variable length decoder 2 output structure movement data 7 and gives the prediction structure data 9 out. The structure decoder 10 receives the structure coded data 6 generated by the parse / variable length decoder 2 and the prediction structure data obtained by the motion compensator 8th and receives the decoded structure data 11 ,

Next, the operation of the syntax analysis / variable-length decoder will be described 2 described.

4 FIG. 10 is a block diagram showing a configuration of the syntax analysis / variable-length decoder. FIG 2 shows. In this figure, the Be zugszahl 21 a header information analyzer for extracting the to the coded bit stream 1 added header information and setting various pieces of header information required for the subsequent decode control; 22 denotes a macroblock layer parser for obtaining the texture coded data 6 and the structural motion data 7 from the coded bit stream 1 ,

5 FIG. 16 is a block diagram showing a configuration of the header information analyzing apparatus. FIG 21 shows. In this figure, the reference numeral designates 30 a VO star code detector used to capture the VO start code 231 in the bitstream 1 is coded; 31 denotes a VOL start code detector for detecting the VOL start code 233 from the coded bit stream 1 ; and 32 denotes a coding scheme determining section for making a determination as to whether the coded bit stream 1 the MPEG-4 compatible H.263 coded bitstream 203 or the MPEG-4 encoded bitstream 204 and to output H.263-compatible identification information 33 , The reference number 34 denotes a switch section which is switched in response to the particular coding scheme; 35 denotes an H.263 picture header information analyzing apparatus for decoding from the MPEG-4 compatible H.263 coded bit stream 203 the header information 222 , which are the picture coding information unique to the H.263 system, and setting the VOL intent information 234 and the VOP header information 236 which are the picture coding information unique to the MPEG-4 system; 36 denotes a H.263 GOB header analysis apparatus for decoding from the MPEG-4 compatible H.263 coded bit stream 203 the H.263 GOB (group of blocks) ancillary information 224 and for updating the from the H.263 frame analyzer 35 set VOP header information 236 depending on the decoded GOB header information 224 ; 37 denotes a VOL header information decoder for decoding the VOL header information 234 from the MPEG-4 encoded bitstream 204 ; and 38 denotes a VOP header information analyzing device for decoding the VOP header information 236 from the MPEG-4 encoded bitstream 204 ,

Next, the operation of the header information analyzer 21 described.

Upon detection of the VO start code 231 in the MPEG-4 compatible H.263 coded bit stream 203 or in the MPEG-4 encoded bitstream 204 to 2 The VO Star Code Detector starts 30 the following decoding process. In particular, the VOL start code detector detects 31 the VOL start code 233 in the coded bit stream 1 , The coding scheme determination section 32 decoded from the coded bit stream 1 the H.263-compatible identification information 226 and leads based on the H.263-compatible identification information 226 the determination by whether the coded bitstream 1 the MPEG-4 compatible H.263 coded bitstream 203 or the MPEG-4 encoded bitstream 204 is, and thereby gives the H.263-compatible identification information 33 out.

If the coded bitstream 1 the MPEG-4 compatible H.263 coded bitstream 203 is the switch section provides 34 the coded bitstream 1 to the H.263 picture header information analyzer 35 ,

6 FIG. 15 is a block diagram showing a configuration of the H.263 picture header information analyzing apparatus. FIG 35 shows. If an H.263 picture start code detector 41 the picture start code 221 in the coded bit stream 1 detects, decodes a subsequent H.263 header information decoder 42 the header information 222 from the coded bit stream 1 , Then sets an MPEG-4 header information setting section 43 the VOL header information 234 and the VOP header information 236 depending on the decoded picture header information 222 ,

7 FIG. 10 is a block diagram showing a configuration of the H.263 picture header information decoder. FIG 42 shows. A time reference (TR) decoder 51 receives the bitstream 1 from the H.263 picture start code detector 41 and decodes the number of pictures (TR) from the transferred pictures that are skipped or not referenced. This information will be used for the display, if necessary.

Then an image type decoder (PTYPE) decoder decodes 52 the image type (PTYPE). The image type contains information such as an image format 301 , an image coding type 302 and an optional mode indicator flag 303 , The picture format 301 and the picture coding type 302 are decoded to the in 6 shown MPEG-4 header information setting section 43 delivered.

The image type (PTYPE) decoder 52 makes a determination as to whether the optional mode indicator flag 303 A is or not. Although the H.263 standard offers several optional modes of operation, the image decoding apparatus described in the present embodiment does not ensure compatibility between bitstreams containing the optional modes. Thus, the coded bit stream in which the optional mode is ON (valid) becomes a decoding process completion section 54 over a scarf terabschnitt 53 so that the decoding process completion section 54 ends the coding process of the coded bit stream. The image type contains information that defines the ad or others that are available as required.

In contrast, the bit stream where the optional mode is OFF (invalid) becomes a picture quantization step size (PQUANT) decoder 55 over the switch section 53 delivered. The image quantization step size (PQUANT) decoder 55 decodes an image quantization step size (PQUANT) 304 , The decoded image quantization step size 304 becomes the MPEG-4 header information setting section 43 to 6 delivered. The header information will be after the image quantization step size 304 skipped, since they are not required in the subsequent decoding.

Next, the operation of the in 6 shown MPEG-4 header information setting section 43 described.

The MPEG-4 header information setting section 43 sets depending on the decoded picture header information 222 VOL geometry information and the object size as the VOL header information 234 , It also sets in the case of the MPEG-4 compatible H.263 encoded bitstream the information indicating that the geometry information represents rectangles, in which case the individual bitstreams respectively correspond to frames. Further, since the size of the object corresponds to the frame size, the MPEG-4 header information setting section obtains 43 the frame size of the image format 301 , one of the image header information 222 , and sets the object size. Furthermore, it also sets information about whether the gray scale per pixel is 8 bits or not. Since the H.263 system assumes that the gray scale per pixel is always 8 bits, they are set to 8 bits.

Next, make the MPEG-4 header information setting section 43 invalidating the MPEG-4 based coding conditions, ie sprite coding, error resistance coding, intra AC / DC prediction and scalability coding. Since MPEG-4 can select its quantization scheme from the two schemes H.263 and MPEG-1/2, the quantization scheme is previously set at H.263 if the MPEG-4 compliant H.263 encoded bitstream 203 is used.

Further, the MPEG-4 header information setting section sets 43 the VOP header information 236 , In particular, it sets as the VOP header information 236 the VOP prediction type information and the quantization step size. The VOP prediction type includes intra coding, which uses only the data within the VOP, and intercoding, which also uses data before and after the VOP. The VOP prediction type information becomes dependent on a picture coding type 302 set, one of the header information 222 , The VOP quantization step size becomes according to an image quantization step size 304 set, one of the header information 222 ,

Moreover, since the MPEG-4 can select its motion vector search area from seven types, it has a code for designating the motion vector search area. Since the H.263 corresponds to only one of the search area, it is required that the MPEG-4 header information setting section 43 sets the motion vector search area designation code according to the motion vector search area the H.263 uses. In addition, although the MPEG-4 interlaced image is compatible, the H.263 interleave is incompatible. Thus, information about the display of the interleaving operation is always invalidated.

After the in 5 H.263 picture header information analyzer shown 35 has completed the analysis of the image header information, the H.263 GOB header information analyzing apparatus starts 36 with the analysis of GOB header information 224 when the coded bit stream is the GOB start code 223 and GOB header information 224 contains. If the coded bit stream is not the GOB start code 223 or GOB header information 224 contains, the H.263 GOB header information analyzer operates 36 Not.

8th is a block diagram showing a configuration of the in 5 H.263 GOB header information analyzer shown 36 shows. If a GOB start code detector 61 the encoded bitstream 1 attached GOB start code 223 detects, decodes a GOB header information decoder 62 the GOB header information 224 ,

9 illustrates GOBs. As shown in this figure, each GOB includes a series of macroblocks formed by dividing an image and the GOB header information 224 contain information required to establish resynchronization on a decoder page. A bit error in the coded bitstream propagates to subsequent macroblock data in the case of variable length coding or predictive coding, thereby affecting correct decoding. The detection of the GOB header information can prevent the propagation of the error since it establishes the resynchronization of the encoded bitstream prior to the decoding of the initial macroblock of the GOB and thus the deco tion of the subsequent macroblocks. The quantization step size and the motion vector of each macroblock must be set again when the resynchronization is established since they are subjected to predictive coding that encodes the differences between the quantization step sizes and between the motion vectors of the current and previous encoded macroblocks.

10 FIG. 10 is a block diagram showing a configuration of a GOB header information decoder. FIG 62 shows. A GOB number decoder 71 decodes a GOB number (GN) from the encoded bitstream 1 , A GOB frame identification number decoder 72 decodes the identification number (GFID) of an image to which the GOB belongs. A GOB quantization step size decoder 73 decodes a GOB quantization step size (GQUANT) 305 and deliver them to an MPEG-4 header information update section 63 , as in 8th is shown.

The MPEG-4 header information updating section 63 updated in response to the decoded GOB header information 224 that of the MPEG-4 header information setting section 43 set VOP header information 236 , It is the quantization step size that depends on the GOB intent information 224 is updated. Thus, the GOB quantization step size is placed at the VOP quantization step size. The preceding pieces of information that are set become the macroblock layer parser 22 to 4 delivered.

The in 5 shown coding scheme determination section 32 performs a determination when the H.263-compatible identification information 226 the MPEG-4 show that the coded bitstream 1 the MPEG-4 encoded bitstream 204 is, and gives the H.263-compatible identification information 33 out. The MPEG-4 encoded bitstream 204 is via the switch section 34 to the VOL header information decoder 37 delivered. The VOL header information decoder 37 decodes the VOL header information 234 from the coded bitstream, and the VOP header information analyzer 38 decodes the VOP header information 236 and supplies them to the macroblock layer parser 22 to 4 ,

After setting the previous information, the macroblock layer parser decodes 22 the macroblock data 225 or 239 through the analysis based on the MPEG-4 syntax. However, since the coding scheme of the block data slightly differs between MPEG-4 and H.263, the decoding side must also switch the operation mode.

11 is a diagram showing a layer structure of the macroblock data 225 in the MPEG-4 compatible H.263 bitstream 203 1 shows in the present embodiment. The macroblock consists of four brightness blocks and two color difference blocks. As in 11 1, each macroblock contains macroblock skip determination information 251 , Macroblock Type / Valid Color Difference Block Identification Information 252 Valid block identification information 253 , Difference quantization step size 254 and movement data 255 which are subjected to multiplexing as attribute information.

Here, the macroblock skip determination information shows 251 whether the motion vector equals zero and all the coefficient data within the macroblock in the inter-VOP are zero (the coefficient data is obtained by passing the input image signal (the original signal when it is intra-coded and the difference signal between it and a reference signal). VOP, if it is inter coded) by the DCT, and then by the quantization). If the motion vector is zero and all coefficient data is zero, the following information about the macroblock is excluded from the bitstream and a jump to the next macroblock is made.

The macroblock type in the macroblock type / valid color difference block identification information 252 indicates a macroblock coding type when the macroblock data is encoded (intra) using the original macroblock signal or when the difference signal between the macroblock and the reference macroblock is encoded after the motion compensation prediction (inter), or when the current macroblock is encoded using the quantization step size that is different from the quantization step size of the immediately preceding macroblock.

The identification information 253 for the valid block, indicate whether the coefficient data of the blocks are all zero or not. Although the preceding attribute information is represented by coefficient data (corresponding to block data 256 ) followed by multiplexing into each block, the coefficient data of the block is absent when the identification information 253 for valid blocks indicate that there is an invalid block.

The difference quantization step size 254 are information inserted by multiplexing when the macroblock type indicates that the quantization step size of the current macroblock is different from that of the immediately preceding macroblock, and indicate the difference value from the quantization step size of the preceding macroblock.

12 FIG. 10 is a block diagram showing a configuration of the macroblock layer parser. FIG 22 shows. In this figure, the reference numeral designates 81 a switch section, which depends on geometry information 311 is switched from the MPEG-4 header information setting section 43 were set; 82 denotes a geometry coded data decoder for decoding the geometry coded data in the coded bit stream; 83 denotes a switch section which depends on the VOP prediction type 312 is switched by the MPEG-4 header information setting section 43 was set; 84 denotes a skip determination information decoder for decoding when the VOP prediction type is other than intra coding, the macroblock skip determination information 251 ; 85 denotes a switch section which is dependent on the skip determination information 251 is switched; 86 denotes a skip-connected data setting section for setting all motion vectors and structure data in the macroblock to zero when skipped; and 87 denotes a macroblock type / valid color difference block identification information decoder for decoding the macroblock type 313 and identification information for valid color difference blocks when the VOP prediction type 312 is intra and skipping is not performed.

The reference number 88 denotes a switch section that is responsive to intra-AC / DC prediction operation indication information 315 received from the MPEG-4 header information setting section 43 are set, is switched; 89 denotes an AC predictive indication information decoder for decoding AC predictive indication information; 90 denotes a valid block identification information decoder for decoding the identification information 253 for valid blocks; and 91 denotes a switch section depending on the macroblock type 313 which is the macroblock type / valid color difference block identification information decoder 87 was issued.

The reference number 92 denotes a difference quantization step size null setting section for setting the difference quantization step size to zero; 93 denotes a difference quantization step size decoder for decoding a difference quantization step size 317 ; 94 denotes an adder for adding the difference quantization step size 317 and a VOP quantization step size 318 of the previous block, and to provide a quantization step size 319 to the structure decoder 10 to 3 ; 95 denotes a switch section which is dependent on interlace operation display information 316 received from the MPEG-4 header information setting section 43 supplied, is switched; 96 denotes a interleave information decoder for decoding interleave information; 97 denotes a motion vector decoder for decoding a motion vector (texture motion data 7 ) depending on the macroblock type 313 of the macroblock type / valid color difference block identification information decoder 87 output, the VOP prediction type 312 received from the MPEG-4 header information setting section 43 and the motion vector search area designation information 320 ; and 98 denotes a block data decoder for decoding the coded block data and outputting the structure-coded data 6 to the structure decoder 10 ,

Next, the operation of the macroblock layer syntax analyzer will be described 22 described.

The following description will be made for the coded bitstream 1 consisting of the MPEG-4 compatible H.263 coded bitstream 203 , Regards the MPEG-4 encoded bitstream 204 the description is omitted here, which is described in the ISO / IEC JTCl / SC29 / WG11 MPEG-4 video VM8.0.

First, the switch section switches 81 the output of the encoded bitstream 1 depending on the MPEG-4 header information setting section 43 set geometry information 311 , If the coded bitstream 1 from the MPEG-4 compatible H.263 encoded bitstream 203 is the geometry information 311 Rectangular, and therefore the bitstream 1 directly to the switch section 83 delivered without the decoder 82 to pass through for geometry coded data.

Subsequently, the switch section leads 83 its switching operation in response to the MPEG-4 header information setting section 43 set VOP prediction type 312 by. If the VOP prediction type 312 is intra-decoded, the macroblock type / valid color difference block identification information decoder 87 the macroblock type 313 and the valid color difference block identification information. If the VOP prediction type is on other than intra, the skip determination information decoder decodes 84 the skip determination information 251 of the macroblock. The decoded skip determination information 251 switch the switch section 85 such that when indicating that the macroblock is to be skipped, the adjustment section 86 For data associated with the skip, both the motion vector of the macroblock and the structure data in the macroblock are all set to zero and the decoding of the macroblock is terminated. On the other hand, if the skip determination information is decoded 251 indicate that the macroblock must be skipped, the macroblock type / valid color difference block identification information decoder 87 the macroblock type 313 and the valid color difference block identification information.

Next, the switch section 88 depending on the intra-AC / DC prediction operation indication information 315 received from the MPEG-4 header information setting section 43 were set, switched. The MPEG-4 compatible H.263 encoded bitstream 203 because it has no function to perform the intra-AC / DC prediction and therefore the intra-AC / DC prediction is set invalid when the VOL intent information 235 are set to the identification information decoders 90 for valid blocks without passing through the AC Prediction Indicator Information Decoder 89 pass.

The identification information decoder 90 for valid blocks decodes the identification information 253 for valid blocks for the brightness block in the macroblock. The switch section 91 is switched depending on the macroblock type 313 of the macroblock type / valid color difference block identification information decoder 87 was decoded such that, if the quantization step size of the current macroblock is different from that of the first preceding macroblock, the difference quantization step size decoder 93 the difference quantization step size 317 between the quantization step size of the current macroblock and that of the first preceding macroblock. The decoded difference quantization step size 317 becomes the VOP quantization step size 318 of the first preceding macroblock by the adder 94 is added and the sum becomes the structure decoder 10 to 3 as the quantization step size 319 delivered.

In contrast, when the quantization step size of the current macroblock is equal to that of the first preceding macroblock, the difference quantization step size nulling section sets 92 the difference quantization step size to zero.

Hereinafter, the switch section 95 depending on the interleaving operation display information 316 received from the MPEG-4 header information setting section 43 were fed, switched. Regarding the MPEG-4 compatible H.263 encoded bitstream 203 At this time, since it does not correspond to the interlaced image, the interleave operation is invalidated, and therefore it becomes the motion vector decoder 97 supplied without the interleave information decoder 96 pass. The motion vector decoder 97 when the MPEG-4 header information setting section decodes 43 set VOP prediction type 312 is equal to the motion vector (structural motion data 7 ) depending on the macroblock type / valid color difference block identification information decoder 87 decoded macroblock type 313 and the one of the MPEG-4 header information setting section 43 set motion vector search area designation information 320 and supplies the motion vector to the motion compensator 8th to 3 ,

Subsequently, the block data decoder decodes 98 the coded block data in the coded bit stream. 13 FIG. 16 is a block diagram showing a configuration of the block data decoder. FIG 98 shows. In this figure, the reference numeral designates 101 a switch section which receives the coded block data and in response to the macroblock type / valid color difference block identification information decoder 87 supplied macroblock type 313 is switched; 102 denotes a switch section which is activated in response to the MPEG-4 header information setting section 43 set intra-AC / DC prediction operation display information 315 is switched; 103 denotes a fixed-length DC coefficient decoder which, when the intra-AC / DC prediction is OFF, executes the decoding of the fixed-length DC coefficient depending on the gray scale per pixel 321 received from the MPEG-4 header information setting section 43 and a decoded intra-DC coefficient 111 outputs; and 104 denotes a DC coefficient decoder which decodes the DC coefficient when the intra-AC / DC prediction is ON, and the decoded intra-DC coefficient 111 outputs.

The reference number 105 denotes a switch section depending on the identification information 253 for valid blocks generated by the identification information decoder 90 for valid blocks, is switched; and 106 denotes an AC coefficient VLD table switch section for switching an AC coefficient variable length (VLD) table depending on the macroblock type 313 of the macroblock type / valid color difference block identification information decoder 87 and H.263-compatible identification information 33 derived from the coding scheme determining section 32 were fed.

The reference number 107 denotes a variable-length AC coefficient data decoder which performs decoding of the variable-length AC coefficient data and decoded AC coefficient data 112 outputs; 108 denotes a switch section which depends on the H.263-compatible identification information 33 derived from the coding scheme determining section 32 to be supplied; 109 denotes a fixed-length AC coefficient data decoder for outputting the decoded AC coefficient data 112 ; 110 denotes an AC coefficient data Esc coding decoder for outputting the decoded AC coefficient data 112 ; and 113 denotes an AC coefficient zeroing section for setting the AC coefficient to zero.

Next, the operation of the block data decoder will be described 98 described.

First, the coded block data is passed through the switch section 101 switched depending on the macroblock type 313 of the macroblock type / valid color difference block identification information decoder 87 is supplied so as to the switch portion 105 supplied when the macroblock type 313 other than intra. If the macroblock type 313 is intra, the coded block data becomes the switch section 102 supplied in response to the intra-AC / DC prediction operation display information 315 is switched from the MPEG-4 header information setting section 43 were set.

Regarding the MPEG-4 compatible H.263 encoded bitstream 203 because of the intra-AC / DC prediction operation 315 is not set by the DC coefficient decoder 104 but to the DC coefficient decoder 103 delivered with fixed length. The DC coefficient decoder 103 Fixed length decoding performs the fixed length decoding and provides the decoded intra DC coefficient 111 to the structure decoder 10 and the coded block data to the switch section 105 , In this case, the length of the code passing through the fixed-length decoding is equal to the gray scale per pixel (the standard is 8 bits). 321 specified by the MPEG-4 header information setting section 43 was set. Because the gray scale per pixel 321 has the standard of 8 bits, it is similar to that of the H.263 decoder.

The switch section 105 will depend on the identification information 253 for valid blocks connected by the identification information decoder 90 were decoded for valid blocks, so that if the block is invalid, the AC coefficient zero set section 113 the decoded AC coefficient data 112 in the block sets to zero and sends it to the structure decoder 10 supplies. If the block is valid, the coded block data becomes the AC coefficient VLD table switch section 106 delivered.

The AC coefficients in the block become variable coding Length through the encoder side subjected the coefficients in the block in a predetermined sequence and it encodes with the generation a combination consisting of a label (LAST) indicating whether a nonzero coefficient is the last in the block, and the number of consecutive zeros (RUN) and the level consecutive nonzero coefficients (LEVEL). The decoder page leads decoding the coded variable-length data, to get the combination (LAST, RUN and LEVEL), so that they can represent the AC coefficients in the block. If the coding the combination (LAST, RUN and LEVEL) of variable length is performed, does that H.263, although the MPEG-4 uses variable encoding different VLC (variable-length coding) tables according to the macroblock type, the Variable length coding using the same VLC table regardless of the macroblock type by.

Thus, in the picture decoding apparatus of the present embodiment, the AC coefficient VLD table switch section is turned on 106 the AC coefficient VLD table depending on the macroblock type 313 of the macroblock type / valid color difference block identification information decoder 87 and the H.263-compatible identification information 33 derived from the coding scheme determining section 32 were fed. If the H.263-compatible identification information 33 where H.263 was set, the AC coefficient data decoder performs 107 variable length decoding by using the single VLD table regardless of the macroblock type (intra or inter) 313 and provides the decoded AC coefficient data 112 to the structure decoder 10 as the coded structure data 6 ,

The coding scheme in the case where the combination (LAST, RUN and LEVEL) is not present in VLC table is also different in MPEG-4 and H.263. If the combination (LAST, RUN, and LEVEL) does not exist in the VLC table When the MPEG-4 encodes the escape code followed by the RUN or LEVEL value correction, it performs either the variable-length coding or the fixed-length coding. In contrast, H.263 encodes the escape code and then performs the fixed-length encoding of the values of LAST, RUN, and LEVEL.

Thus, in the image decoding apparatus of the present invention, when the AC coefficient data decoder provides 107 with variable length detects the escape code in the coded AC coefficient data, it acquires the coded bit stream to the switch section 108 , If the H.263-compatible identification information 33 at H.263, the coded bit stream does not become the AC coefficient data Esc coding decoder 110 but to the AC coefficient data decoder 109 of fixed length so as to perform the fixed-length decoding of the succeeding code via LAST, RUN and LEVEL in their predetermined code length and the decoded AC coefficient data 112 to the structure decoder 10 as the structure-coded data 6 supplies.

The previous operation becomes the structure-coded data 6 and the motion vector (structure motion data 7 ) received from the macroblock layer parser 22 is output to the structure decoder 10 or the motion compensator 8th delivered.

As described above, the in 3 shown syntax analysis / variable length decoder 2 the VOP prediction mode and set it. When the VOP prediction operation is equal to inter, the difference vector in the structural motion vector is decoded. The difference vector in the decoded texture motion vector is the difference vector between the prediction vector obtained from motion vectors of three adjacent macroblocks and the actual motion vector. Thus, the motion vector (texture motion data 8th ) calculated by adding the difference vector of the motion vector to the prediction vector.

The prediction vector is calculated from the motion vectors of the three adjacent macroblocks (MV1, MV2 and MV3) already decoded, as in FIG 14 (a) is shown. If any one of the three adjacent macroblocks is outside the VOP, the motion vector of the macroblock outside the VOP is set to the zero vector, as in FIG 14 (b) or 14 (d) is shown. Alternatively, it may be set using the motion vector of the same macroblock in the VOP, as in FIG 14 (c) is shown. However, if the coding scheme is H.263 and the GOB header is defined, it is necessary for the prediction vector to be set within the boundary of the GOB. The prediction vector is set as in the VOP. Depending on the decoded vector, the prediction vector is extracted as the one to the structure decoder 10 Predictive structure data to be output 9 ,

in the In contrast, when the VOP prediction operation is equal to intra is, the motion compensation prediction is not performed.

The structure decoder 10 receives the structured data 6 and provides the structural data 11 come back.

15 FIG. 12 is a block diagram showing a configuration of the structure decoder. FIG 10 shows. An inverse quantizer 114 performs the inverse quantization of the structure coded data 6 by.

16 FIG. 12 is a block diagram showing a configuration of the inverse quantizer. FIG 114 shows.

A switch section 117 is dependent on the data encoded in the structure 6 contained macroblock type 313 connected. Because the structure coded data 6 are not included in the DC coefficient data when the macroblock type 313 of the block to be decoded is the inter-coded operation, the structure-coded data becomes 6 directly to an inverse AC coefficient quantizer 120 delivered. In contrast, when the macroblock type 313 of the block to be decoded is the intra-coded operation, the structure-coded data 6 to the switch section 118 delivered.

The switch section 118 will depend on the H.263-compatible identification information 33 connected. If the H.263-compatible identification information 33 the MPEG-4 compatible H.263 encoded bitstream 203 A linear inverse DC coefficient quantizer results 119B the inverse quantization of the data encoded in the structure 6 contained DC coefficient data. On the other hand, if the H.263-compatible identification information 33 the MPEG-4 encoded bitstream 204 display, the nonlinear inverse DC coefficient quantizer 119A the inverse quantization of the DC coefficient data and gives a DC coefficient 306 out. The DC coefficient quantization is performed by dividing the DC coefficient by a predetermined value (called a quantization scale) and dropping the fraction. Therefore, the decoding side can use the DC coefficient 306 by multiplying the DC quantization coefficient by the quantization scale. The linear inverse DC coefficient quantizer 119B differs from the nonlinear inverse DC coefficient quantizer 119A in the sow the value of the quantization scale. The linear inverse DC coefficient quantizer 119B performs inverse quantization using a fixed value 8th as a quantization scale. In contrast, the non-linear inverse DC coefficient quantizer 199A the value of the quantization scale is not linear in accordance with the range of the quantization step size 319 and performs the inverse quantization using the quantization scale, thereby increasing the DC coefficient 306 is issued.

The inverse AC coefficient quantizer 120 performs the inverse quantization of the AC coefficient data and gives the AC coefficient 307 out. The DC coefficient 306 (which exists only in the intra-coded operation) passing through the inverse quantization and the AC coefficient 307 become an inverse DC section 115 as a DCT coefficient 308 which is subjected to the inverse DCT, and as a decoded prediction error signal 309 output. An adder 116 adds the decoded prediction error signal 309 to those of the motion compensator 8th obtained predictive structure data 9 and gives the sum as the decoded structure data 11 out. The addition of the prediction structure data 9 is not performed in the intra-coded operation.

If the coded bitstream 1 the H.263-compatible identification information 33 sometimes added an end-of-sequence code (EOS) 227 which indicates the end of the sequence inserted by multiplexing as in 2 (a) is shown. The end-of-sequence code 227 is from the picture start code detector 41 so that the decoding process detects the end-of-sequence code 227 is ended.

As described above, the present embodiment 1 is configured to be the MPEG-4 compatible H.263 coded bitstream 203 received from the H.263 encoded bitstream 201 exists in the the VO start code 231 , the VOL start code, the VO identification number 232 and the H.263-compatible identification information 226 are inserted by multiplexing, and these information words are decoded. This offers the advantage of being able to implement an image decoding apparatus having compatibility between H.263 and MPEG-4.

Embodiment 2

17 FIG. 10 is a block diagram showing a configuration of a picture coding apparatus according to Embodiment 2 which generates a coded bit stream decodable by the picture decoding apparatus described in Embodiment 1. FIG. In this figure, the reference numeral designates 121 an input image signal; 122 denotes a H.263 encoder; 123 denotes a H.263 coded bit stream; 124 denotes an MPEG-4 compatible tag; 125 denotes a header information multiplexer; and 126 denotes an MPEG-4 compatible H.263 coded bitstream.

When next the way of working is described.

First, the H.263 encoder encodes 122 the input image signal 121 correspond to the H.263 syntax and generate the H.263 coded bit stream 123 , Subsequently, the header information multiplexer subjects 125 which is the MPEG-4 compliant identifier 124 which indicates the generation of the bit stream decodable by an MPEG-4 based decoder receives the VO start code before the header of the H.263 bit stream 231 , the VO identification number 232 , the VOL start code 233 and H.263-compatible identification information (a flag of "0" or "1" indicating the H.263-based bit stream) 226 a multiplexing processing required to perform the decoding by the image decoding apparatus described in Embodiment 1. Thus, the content of the MPEG-4 compatible H.263 encoded bitstream becomes 126 which has undergone the multiplexing processing described in 2 (a) shown bitstream, which has been described in connection with the embodiment 1.

If the H.263 encoder 127 a real-time communication with an MPEG-4 decoding device 128 performs as in 18 is shown, the MPEG-4 decoding device 128 the MPEG-4 compatible license plate 124 to the H.263 coding device 127 send and in response to receiving the MPEG-4 compatible license plate 124 can be the H.263 encoder 127 the VO start code 231 , the VO identification number 232 , the VOL start code 233 and the H.263-compatible identification information 226 through multiplexing into the H.263 bit stream 123 insert, which are required to achieve the decoding by the image decoding apparatus described in the embodiment.

As described above, in the present embodiment, 2 becomes the VO star code 231 , the VO identification number 232 , the VOL startup code 233 and the H.263-compatible identification information 226 in the H.263 coded bit stream 123 inserted by multiplexing. This offers the advantage of being able to produce an image coding apparatus capable of producing an encoded bitstream which is decodable by an MPEG-4 compatible image decoding apparatus.

Embodiment 3

19 Figure 12 is a diagram illustrating a structure of an MPEG-4 compatible H.263 encoded bitstream 205 in the present embodiment 3 shows. It contains in addition to the in 1 (a) shown conventional H.263 coded bitstream 201 a VO start code 231 , a VO identification number 232 and a H.263 startup code 228 , The H.263 startup code 228 has the functions of both the VOL start code 233 as well as the H.263-compatible identification information 226 which were inserted in the embodiment 1 by multiplexing.

The MPEG-4 encoded bitstream 202 is identical to the one in 1 (b) shown conventional.

The image decoding apparatus according to the present embodiment differs from the image decoding apparatus described in the embodiment 1 only by the header information analyzing apparatus 21 , 20 FIG. 16 is a block diagram showing a configuration of the header information analyzing apparatus. FIG 21 in the embodiment 3 shows. In this figure, the reference numeral designates 131 an H.263 start code / VOL start code detector; and 132 denotes a code scheme determining section. The VO start code detector 30 , the H.263-compatible identification information 33 , the switch section 34 , the H.263 picture header information analyzer 35 , the H.263 GOB header information analyzer 36 , the VOL header information decoder 37 and the VOP header information analyzer 38 are the same as theirs in 5 for the embodiment shown 1 counterparts.

When next the way of working is described.

Depending on the registration of the VO star code 231 through the VO start code detector 30 the following decoding process is started. First, regarding the MPEG-4 compatible H.263 coded bit stream 205 the H.263 start code / VOL start code detector 131 the H.263 start code, while it regards the MPEG-4 encoded bitstream 202 the VOL start code 233 detected.

In MPEG-4, the start code in each layer consists of a code (0000 0000 0000 0000 0000 0001) common to all start codes, followed by a fixed length start code (5 bits) unique to the layer. The common start code is surely detected as the start code in the bitstream. Thus has the H.263 start code 228 also a structure consisting of the common start code followed by the fixed-length code (5 bits) which allows it to be identified as the H.263 coded bitstream.

If the detected startup code is the H.263 startup code 228 is placed the coding scheme determining section 132 the H.263-compatible identification information 33 at the H.263. In contrast, he places, if the start code is the VOL start code 233 is the H.263-compatible identification information 33 in the MPEG-4. The following process is the same as that in Embodiment 1.

As described above, the present embodiment 3 is designed to be the MPEG-4 compatible H.263 coded bitstream 205 received from the H.263 encoded bitstream 201 where the VO start code exists 231 , the VO identification number 232 and the H.263 startup code 228 are inserted by multiplexing, and these information words are decoded. This offers the advantage of being able to provide an image decoding apparatus having compatibility between H.263 and MPEG-4.

Embodiment 4

The present embodiment 4 is a picture coding apparatus for generating a bit stream which is decodable by the picture decoding apparatus described in the embodiment 3 and has the same configuration as that in FIG 17 shown according to the embodiment 2 has.

When next the way of working is described.

First, the H.263 encoder encodes 122 the input image signal 121 according to the H.263 syntax, whereby the H.263 coded bitstream 123 is produced. Subsequent adds upon receipt of the MPEG-4 compatible license plate 124 the header information multiplexer 125 before the header of the H.263 bit stream the VO start code 231 , the VO identification number 232 and the H.263 startup code 228 by multiplexing, which are required for implementing the decoding by the picture decoding apparatus described in the embodiment 3. Thus, the content of the multiplexed MPEG-4 compatible H.263 coded bitstream becomes 126 equivalent to that of 19 shown and described in connection with the embodiment 3 bitstream.

The MPEG-4 compatible license plate 124 can from the MPEG-4 decoding device 128 be transmitted as in connection with 18 for the embodiment 2 has been described.

As described above, at the present embodiment 4, the VO start code 231 , the VO identification number 232 and the H.263 startup code 228 through multiplexing into the H.263 bit stream 201 inserted. This offers the advantage of being able to provide an image coding apparatus capable of generating an encoded bitstream which is decodable by the MPEG-4 compatible image decoding apparatus.

Embodiment 5

The present embodiment 5 has a multiplexer for inserting the header information for the production of MPEG-4 compatibility, for example, in a network independent of a coding device. 21 FIG. 15 is a diagram showing an image communication system according to the present embodiment 5. FIG. In this figure, the reference numeral designates 141 an H.263 coding device; 142 denotes an MPEG-4 decoding apparatus; and 143 denotes a coded bit stream conversion device. The H.263 coding device 141 , the MPEG-4 decoding device 142 and the conversion device 143 for a coded bit stream are connected to a network.

When next the way of working is described.

When receiving an MPEG-4 compatible license plate 147 containing an MPEG-4 compatible H.263 encoded bitstream 148 from the MPEG-4 decoding device 142 or requested by a user receives the conversion device 143 for a coded bitstream, a H.263 coded bitstream 146 from the H.263 encoder 141 , multiplexes the header information into the H.263 encoded bitstream 146 required by the MPEG-4 decoding apparatus for performing the decoding as described in Embodiment 2 or 4, and transmits the multiplex data to the MPEG-4 decoding apparatus 142 ,

As described above, the present embodiment 5 has the conversion device 143 for a coded bit stream in the network. This offers the advantage of being able to provide an image communication system that has compatibility between H.263 and MPEG-4.

Embodiment 6

22 FIG. 15 is a diagram showing an image communication system in the present embodiment 6. FIG. In this figure, the reference numeral designates 141 the H.263 coding device; 143 denotes the coded bit stream converting device; 144 denotes a server; and 145 denotes a built-in type browser MPEG-4 decoding apparatus connected to a network.

When next the way of working is described.

When the MPEG-4 decoding device 145 from a built-in browser type access to the H.263 coded bit stream 146 When it is transmitted over the network, it transmits the MPEG-4 compliant identifier 147 indicating the decoding by the MPEG-4 decoding apparatus to the server 144 , When receiving the MPEG-4 compatible license plate 147 transmits the server 144 the H.263 coded bit stream 146 to the conversion device 143 for a coded bit stream.

The conversion device 143 for a coded bitstream generates the MPEG-4 compatible H.263 coded bitstream 148 which is decodable by the MPEG-4 decoding apparatus by adding header information to the received H.263 bit stream 146 as described in Embodiment 2 or 4, and transmits it to the MPEG-4 decoding apparatus 145 of the type built in the browser. When receiving the MPEG-4 compatible H.263 encoded bitstream 148 can the MPEG-4 decoding device 145 of the type built into the browser, the H.263-encoded bitstream 146 decode to display images.

The MPEG-4 decoding device 145 of the type built into the browser itself can also be the conversion device 143 included for the encoded bitstream. In this case, the MPEG-4 decoding device receives 145 of the type built into the browser, the H.263-encoded bitstream 146 from the server 144 and converts the MPEG-4 compatible H.263 encoded bitstream 148 so that the built-in MPEG-4 decoder can decode it to display images.

As described above, the present embodiment 6 in the network, the coded bit stream converting device and the server up. This offers the advantage of being able to to provide an image communication system that provides compatibility between H.263 and MPEG-4 owns.

Embodiment 7

The picture decoding apparatus described in the foregoing embodiments 1 and 3 can distinguish the H.263 bit stream from the MPEG-4 bit stream. You can, however does not receive the H.263 bit stream as it is because the header information to make it MPEG-4 compliant must be multiplexed at the initial location of the H.263 bitstream generated by the H.263 encoder , Embodiment 7 is an image decoding apparatus capable of receiving the H.263 bit stream without any change.

23 FIG. 16 is a block diagram showing a configuration of the header information analyzing apparatus. FIG 21 in the present embodiment 7 shows. In this figure, the reference numeral designates 151 an H.263 picture start code detector for detecting an H.263 picture start code 221 multiplexed in the H.263 coded bit stream by multiplexing; 152 denotes a coding scheme determining section; and 153 denotes a H.263 picture header information analyzing apparatus for setting the VOL header information and the VOP header information in accordance with the picture header information 222 multiplexed into the H.263 encoded bitstream. The remaining VO start code detector, H.263-compatible identification information 33 , Switch section 34 , H.263 GOB header information analyzer 36 , VOL header information decoder 37 and VOP header information analyzer 38 correspond to those of the embodiment 1 , The components other than the header information analyzing device 21 are equivalent to those of the image decoding apparatus according to Embodiment 1.

When next the way of working is described.

The H.263 picture start code detector 151 always monitors the beginning and the end of the coded bit stream, as in 24 (a) and 24 (b) is shown. It monitors as a continuous coded bit stream from the picture start code 221 to the macroblock data 225 in the H.263 coded bit stream 201 , and from the VO startup code 231 up to the macroblock data 239 in the MPEG-4 encoded bitstream 202 ,

Upon receipt of the H.263 encoded bitstream 201 detects the H.263 picture start code detector 151 the picture start code 221 and supplies the result to the coding scheme determining section 152 , The coding scheme determination section 152 makes a determination based on the picture start code 221 in that the received coded bitstream is the H.263 coded bitstream 201 and places the H.263-compatible identification information 33 at H.263. In contrast, if the VO start code detector 33 the VO start code 231 detects, the coding scheme determining section 152 the determination that the received encoded bitstream is the MPEG-4 encoded bitstream 202 and places the H.263-compatible identification information 33 at MPEG-4.

Regards the H.263 encoded bitstream 201 supplies the switch section 34 to the H.263 picture header information analyzer 153 , The H.263 picture header information analyzer 153 decodes the multiplexed processing into the H.263 encoded bitstream 201 inserted header information 222 and sets the VOL header information and the VOP header information as in Embodiment 1. The following procedure is the same as that in Embodiment 1.

On the other hand, regarding the MPEG-4 encoded bitstream 202 the switch section 34 this to the VOL header information decoder 37 , The following procedure is the same as that in Embodiment 1.

As described above, the present embodiment 7 determines that the bit stream is the H.263 coded bit stream 201 is when the picture start code 221 is detected, and sets the VOL header information and the VOP header information. This offers the advantage of being able to provide an image decoding apparatus having compatibility between H.263 and MPEG-4.

Embodiment 8th

The present embodiment 8 relates to a coded bit stream converting apparatus for converting the in 1 (a) H.263 coded bit stream shown 201 in the 1 (b) shown MPEG-4 encoded bitstream 202 ,

25 FIG. 10 is a block diagram showing the coded bit stream converting apparatus of Embodiment 8. FIG. In this figure, the reference numeral designates 161 a syntax analyzer for splitting the H.263 coded bit stream 201 in a header information code word 401 , a GOB header information code word 402 and a macroblock data codeword 403 ; 162 denotes a picture header information decoder for decoding the picture header information code word 401 ; 163 denotes a GOB header information analyzer / converter for decoding the GOB header information codeword 402 ; 164 denotes an MPEG-4 header information setting section for setting the VOL header information 234 and the VOP header information 236 ; and 165 denotes a multiplexer for generating the MPEG-4 encoded bitstream 202 ,

When next the way of working is described.

The parser 161 splits when it receives the image startup code 221 in the H.263 coded bit stream 201 detects the subsequent coded bit stream in the header information codeword 401 , the GOB header information codeword 402 and the macroblock data codeword 403 and supplies them to the header information decoder 162 , the GOB header information analyzer / converter 163 and the multiplexer 165 , The GOB header information codeword 402 is not necessarily by multiplexing in the H.263 coded bit stream 201 but is inserted by multiplexing as long as the GOB startup code 223 is detected. If the GOB start code 223 is detected, the GOB-header detection information 404 to the MPEG-4 header information setting section 164 delivered. The header information decoder 162 decodes the header information codeword 401 as in the embodiment 1 and provides the decoded image header information 405 to the MPEG-4 header information setting section 164 ,

In response to the decoded header information 405 sets the MPEG-4 header information setting section 164 the VOL header information 234 and the VOP header information 236 as in Embodiment 1. Regarding the header information not referred to in Embodiment 1, any value disclosed in ISO / IEC JTC1 / SC29 / WG11 MPEG-4 Video VM8-0 may be set. When the MPEG-4 header information setting section 164 the GOB headset detection information 405 receives, it allows the error resistance coding command operation.

As in the embodiment 1, the decoding process of the macroblock data differs from H.263 of that to MPEG-4. Accordingly, the decoding side needs the Decoding method in dependence change from switching information. That's why the following switching information is set in the VOL header.

(1) AC coefficient VLC table switching information.

information for switching VLD tables used to perform the variable length coding of the AC coefficient data can be used on the decoding side when the encoding side different VLC tables for performing the Variable length coding the AC coefficient data used, as in the embodiment 1 is described.

(2) Esc coding switching information.

information for switching decoding schemes on the decoding side when the Encoding side uses different coding schemes in the case in which the AC coefficient data is not present in the VLC tables when the variable-length coding of the AC coefficient data is performed, as in the embodiment 1 is described.

(3) Inverse intra-DC coefficient quantization switching information

information for switching the inverse quantization method of the DC coefficients when the encoding side has different intra-DC coefficient quantization methods used, as in the embodiment 1 is described.

The Switching information items the above points (1) - (3) can integral as information for switching between the one used by H.263 Technique and other techniques are set.

The one of the MPEG-4 header information setting section 164 set MPEG-4 header information is subjected to the variable-length coding and to the multiplexer 165 as MPEG-4 header information codeword 406 delivered.

The GOB header information analyzer / converter 163 decodes the GOB header information codeword 402 as in Embodiment 1, and converts the GOB header information 224 in the resynchronization information 238 in the MPEG-4 representation.

The MPEG-4 resynchronization information 238 are used as an error resistance amplifier and multiplexed when the error resistance coding display information of the VOL header information 236 are valid. If the resynchronization information 238 the decode page resynchronizes with the encoded bitstream and resets the prediction vector and quantization step size used to decode the macroblock. At H.263, the prediction vector and the quantization step size are restored when the GOB intent information 224 be decoded. Therefore, the conversion allows the GOB header information 224 using the resynchronization information 238 that the GOB intent information 224 converted to the MPEG-4 representation.

26 is a diagram showing a structure of GOB header information 224 and the resynchronization information 238 shows. A macroblock number 271 in the resynchronization information 238 is the number indicating the position of the macroblock in the VOP. It can be obtained by calculating the position of the macroblock corresponding to the received H.263 macroblock data in the image. Since it corresponds to the first macroblock in the GOB, it can be calculated from the GOB number. A quantization scale 272 is obtained by setting the GOB quantization step size. A preamble extension command code 273 is "1" if a time reference 274 and an elapsed VOP time 275 be subjected to multiplexing. These data words of the information are used to represent the individual VOPs. The time reference 274 and the elapsed VOP time 275 can be set as needed if the preamble extension command code 273 is set to "1". The resynchronization information 238 are subjected to variable length coding, allowing the multiplexer 165 a resync information codeword 407 which contains a resync instruction code, ie a unique fixed length code indicating that the resynchronization information 238 have been subjected to multiplexing.

The multiplexer 165 performs multiplexing of the MPEG-4 header information codeword 406 , the resynchronization information codeword 407 and the macroblock data codeword 403 to obtain the encoded bitstream and supplies it to the MPEG-4 encoded bitstream 202 ,

Although it is assumed that the resynchronization information is to be multiplexed when the error-resistant coding display information of the VOL header information 234 In the present embodiment, they may be subjected to multiplexing regardless of whether the error-resistant coding display information is valid or invalid.

The parser 161 ends its analysis when it's the end-of-sequence code 227 in which case the end-of-sequence code is detected 227 after the macroblock data 225 in the H.263 coded bit stream 201 are added.

As described above, the present embodiment converts the H.263 coded bit stream 201 in the MPEG-4 encoded bitstream 202 around. This offers the advantage of being able to decode the H.263 encoded bitstream by the MPEG-4 image decoder.

Embodiment 9

Although in the embodiment 7 after 23 the coding scheme determining section 152 the H.263 coded bit stream 201 identifies when the H.263 picture start code detector 151 the picture start code 221 and the H.263 picture header information analyzer 153 set the VOL header information and the VOP header information, the present embodiment switches the operation of the macroblock layer parser 22 depending on the header information 222 generated by the H.263 header information decoder 42 were decoded, as in 6 shown in the H.263 picture header information analyzer 153 is included. This may be the MPEG-4 header information setting section 43 unnecessary. Additionally, if the GOB start code detector is decoded 61 of the embodiment 7 to 8th the GOB start code 223 in the H.263 coded bit stream 201 detects, the GOB header information decoder 62 the GOB header information 224 , and the MPEG-4 header information updating section 63 sets the in the VOP header information 236 contained VOP quantization step size back. However, the H.263 encoded bitstream is 201 in the present embodiment, that in the header information 222 included image quantization step size 304 to reset the macroblock data using the image header information 222 to decode.

Next, the operation of the macroblock layer parser will be described 22 described when the macroblock data is decoded depending on the image header information 222 generated by the H.263 header information decoder 42 were decoded.

Since the present embodiment is in the operation of the switch sections 81 . 83 . 88 and 95 , in the operation of the adder 94 and in the operation of the motion vector decoder 97 in the in 12 The macroblock layer parser shown differs and operates in the operation of the switch section 102 in the 13 shown block data decoder 98 differs, only the different parts are described.

If the MPEG-4 encoded bitstream 202 is decoded, that is, when MPEG-4 through the H.263-compatible identification information 33 denoted by the coding scheme Be atmospheric section 152 to 23 are set, the switch section 81 in response to the VOL header information decoder 37 decoded geometry information. In contrast, when the H.263 coded bitstream 201 is decoded, that is, if the H.263-compatible identification information 33 H.263, the bitstream 1 unconditionally to the switch section 83 delivered without the decoder 82 to pass through for geometry coded data.

If the MPEG-4 encoded bitstream 202 is decoded, the switch section 83 in response to the VOP header information analyzer 38 decoded VOP prediction type switched. On the other hand, when the H.263 coded bitstream 201 is decoded, the switch section 83 in response to the H.263 header information decoder 42 decoded picture coding type 302 connected. The switching operation itself is the same as that in the embodiment 1, and is performed depending on whether the image coding type 302 intra or not.

If the MPEG-4 encoded bitstream 202 is decoded, the switch section 88 in response to the VOL header information decoder 37 decoded intra-AC / DC predictive indication information. When the H.263 coded bitstream 201 is decoded, that is, if the H.263-compatible identification information 33 H.263 will show the bitstream 1 unconditionally to the identification information decoder 90 for valid blocks without passing through the AC Prediction Indicator Information Decoder 89 pass.

If the MPEG-4 encoded bitstream 202 is decoded, the adder adds 94 the VOP quantization step size of the first preceding decoded macroblock to the decoded difference quantization step size 254 and outputs the sum as the quantization step size. In contrast, it adds when the H.263 encoded bitstream 201 is decoded, the decoded image quantization step size of the first preceding macroblock to the decoded difference quantization step size 254 and outputs the sum as the quantization step size.

If the MPEG-4 encoded bitstream 202 is decoded, the switch section 95 in response to the VOP header information analyzer 38 decoded interleaving operation display information. When the H.263 coded bitstream 201 is decoded, that is, when the H.263-compatible identification information 33 H.263 will show the bitstream 1 unconditionally to the motion vector decoder 97 supplied without the interleave information decoder 96 pass.

If the MPEG-4 encoded bitstream 202 is decoded, the motion vector decoder decodes 97 the motion vector (structure motion data 7 ) in response to the VOP header information analyzer 38 decoded motion vector search area designation information. When the H.263 bit stream is decoded, the motion vector decoder decodes 97 the motion vector (structure motion data 7 ) depending on the motion vector search range defined by H.263.

If the MPEG-4 encoded bitstream 202 is decoded, the switch section 102 in the block data decoder 98 in response to the VOL header information decoder 37 decoded intra-AC / DC prediction operation display information. When the H.263 coded bitstream 201 is decoded, that is, when the H.263-compatible identification information 33 H.263 will show the bitstream 1 unconditionally to the DC coefficient decoder 103 delivered with fixed length. The subsequent operation is the same as that in Embodiment 1.

As described above, the embodiment 9 is arranged to make a determination that the bit stream is the H.263 coded bit stream 201 is when it's the picture startup code 221 captured, the header information 222 decodes and the macroblock data in dependence on the decoded picture header information 222 decoded. This offers the advantage of being able to provide the picture coding apparatus having compatibility between H.263 and MPEG-4 without setting the VOL header information and the VOP header information.

INDUSTRIAL APPLICABILITY

As described above can the picture decoding apparatus, the picture coding apparatus, the picture communication system and the conversion device for an encoded bitstream according to the present invention Invention the coded bitstream of a different coding scheme transmit and receive in a simple configuration.

Claims (1)

A bit stream generating apparatus comprising: a header information multiplexing device for multiplexing a first coded bit stream coded in the H.263 coding scheme, containing the first header information of H.263-Co and the second header information of the MPEG-4 encoding scheme before the first header information for ensuring compatibility with the MPEG-4 encoded bit stream encoded in the MPEG-4 encoding scheme, the header information multiplexing unit decompressing the encoded image data Video object start code and the video object identification number of the MPEG-4 encoding scheme is multiplexed as the second header information to ensure compatibility with the MPEG-4 encoded bit stream.