FR2915341A1 - Image data block coding method, involves generating prediction block from data block of base layer and another data block of enhancement layer spatially near third block, where former and latter blocks are previously coded and reconstructed - Google Patents

Abstract

The method involves generating an image data prediction block from an image data block of a base layer and another image data block of an enhancement layer spatially near a third image data block, using an over sampling module and an image data prediction block generating module. The former block and the latter block are previously coded and reconstructed using respective coding modules. A residue block is generated from the prediction block and the third data block using a subtraction module. The residue block is coded using a coding unit. Independent claims are also included for the following: (1) a device for coding a sequence of images presented in the form of base and enhancement layers (2) a method for decoding a part of a bit stream representative of a sequence of images presented in the form of base and enhancement layers (3) a device for decoding a part of a bit stream representative of a sequence of images presented in the form of base and enhancement layers (4) a coded bit stream representative of a sequence of images presented in the form of base and enhancement layers.

Description

DEVICE AND METHOD FOR SCALABLE FORMAT CODING OF A DATA BLOCK

  1. Field of the Invention The invention relates to a method for coding an image data block of an image sequence and a method for decoding part of a train. scalable binary for reconstructing an image data block of a sequence of images. It also relates to a device for encoding an image sequence in scalable (or scalable) form. The invention also relates to a device for decoding a scalable binary train with a view to reconstructing a sequence of images.

  2. State of the Art With reference to FIG. 1, a coding device ENC1 makes it possible to code, in scalable form, a sequence of images in the form of a base layer (BL layer) and of FIG. at least one enhancement layer (EL layer). The images of the BL layer divided into blocks of pixels, denoted BBL, are generally sub-sampled versions of the images of the EL layer themselves divided into blocks of pixels, denoted MBEL. The coding device ENC1 comprises a first coding module ENC BL1 for coding the layer BL and at least a second coding module ENC_EL1 for coding the layer EL. Generally, it further comprises a MUX module connected to the encoding modules ENC_BL1 and ENC_EL1 for multiplexing the bitstreams generated by said encoding modules ENC BL1 and ENC EL1. The multiplexing module MUX may be external to the encoding device ENC1. The first encoding module ENC_BL1 generally encodes the image data blocks of the BL layer in intra or inter mode in accordance with a video coding standard known to those skilled in the art of video encoders such as MPEG-2, MPEG-4 AVC, H.261, H.262, H.263, etc. Moreover, in order to reduce the spatial redundancy between the images of the EL layer, the second encoding module ENC_EL1 is adapted to code EL EL image data blocks according to conventional intra or inter coding modes, ie by spatially predicting , respectively temporally said blocks of image data from other image data blocks of the EL layer. With reference to FIG. 2, the second coding module ENC_EL1 makes it possible in particular to predict and code a block MBEL of image data of the layer EL in intra mode from blocks of image data (eg A, B, C and D in FIG. 2) spatially adjacent to said MBEL block and previously coded and then reconstructed. For example, the MBEL block is predicted according to one of the 9 spatial prediction modes defined by the MPEG-4 AVC standard in ISO / IEC 14496-10 entitled Information technology - Coding of audio-visual objects - Part 10 : Advanced Video Coding. In addition, in order to reduce the redundancy between the images of the layer BL and the images of the layer EL, the second code module ENC_EL1 is also adapted to encode an image data block MBEL of the layer EL from one or of several BBL blocks of image data of the layer BL according to an inter-layer coding mode (inter-layer in English). For this purpose, the second encoding module ENC_EL1 is adapted to predict the MBEL image data block from one or more blocks of corresponding BBL image data in the base layer previously coded, reconstructed, and then oversampled in order to generating an inter-layer prediction block denoted MBBP. The reconstructed picture data blocks are denoted BB ~. The image data is texture, i.e., luminance or chrominance image data, or residue image data. For example, according to the scalable video encoding standard SVC, in the case where the corresponding BBL blocks of the BL layer are intra-coded then the predicted picture data of the MBEL block is texture image data. On the other hand, in the case where the corresponding blocks of the BL layer are coded in inter mode, then the predicted image data of the MBEL block are residual image data, themselves previously obtained for example by conventional temporal prediction from blocks of data. the EL layer belonging to other images of the sequence. If the corresponding blocks BBL are coded in inter mode for some and intra mode for others then part of the predicted picture data of the MBEL block is residue picture data and another part of the predicted picture data of the MBEL block is data. texture image. These different variants are described in document JVT-T005 of the ISO / IEC MPEG & ITU-T VCEG entitled "Draft of the Joint Draft 7", J.Reichel, H.Schwarz, M.Wien.

  Referring again to FIG. 1, the second coding module ENC_EL1 conventionally comprises a decision module 10 adapted to select, according to a predefined selection criterion, for an MBEL block of the EL layer a coding mode (inter, intra or inter-layer) and an associated prediction mode (eg in the case of the intra coding mode, one of the 9 spatial prediction modes). This selection is, for example, made on the basis of a rate-distortion criterion, i.e. the selected mode is the one that offers the best rate-distortion compromise. In this figure, the modules well known to those skilled in the art of video coders that make it possible to code blocks of the EL layer according to conventional modes (eg intra, inter, etc.) such as those defined in the ISO document. / IEC 14496-10 are not shown (eg motion estimation module). The second coding module ENC_EL1 comprises a module 20 for oversampling, eg by bilinear interpolation, of BBi image data blocks reconstructed by the first coding module ENC_BL1 in order to obtain the MBBP inter-layer prediction block. . The second coding module ENC_EL1 further comprises a module 30 adapted to subtract pixel by pixel the MBBP prediction block from the image data block MBEL of the enhancement layer. The module 30 thus generates a residue block denoted MBES1dus which is then transformed, quantized and coded by a module 40. The image data blocks BBi reconstructed by the first coding module ENC_BL1 and consequently the MBBP prediction block contain a smoothed signal, ie having lost some of the high spatial frequencies present in the original signal. This loss of high spatial frequencies is due to the fact that the images of the BL layer are generally obtained by sub-sampling the images of the EL layer. It is also due to the quantization of the image data blocks of the layer BL operated by the first coding module ENC_BL1. As a result, the MBELIdus residue block generated by the module 30 has a greater non-zero number of residuals (also called residual coefficients) than if the signal in the BBl block had not been smoothed. Therefore, the number of bits necessary to code said MBES1dus residue block is greater than if the signal in the BBl block had not been smoothed. SUMMARY OF THE INVENTION The object of the invention is to overcome at least one drawback of the prior art.

  For this purpose, the invention relates to a method for coding an image data block, called a current block, of a sequence of images in the form of a base layer and at least one layer of improvement, the current block belonging to the enhancement layer. The coding method comprises the following steps: generating, for the current block, an image data prediction block; generating a block of residues from the prediction block and the current block; and - encode the residue block. According to an essential characteristic of the invention, the prediction block is generated from at least one block of image data of the base layer, said corresponding block, and at least one block of image data of the layer of adjacent improvement spatially of the current block, said neighboring block, the corresponding block and the neighboring block having been previously coded and reconstructed. The coding method according to the invention makes it possible to enrich the prediction signal by adding to the image data originating from the corresponding block or blocks, high spatial frequencies coming from blocks of the enhancement layer which are spatially neighbors of the current block.

  The invention also relates to a coding device for a sequence of images in the form of a base layer and at least one improvement layer. It comprises a first coding module for coding image data blocks of the base layer and a second coding module for coding image data blocks of the enhancement layer. The second coding module comprises: first means for generating, for an image data block of the improvement layer, said current block, an image data prediction block; second means for generating a block of residues from the prediction block and the current block; and third means for coding the residue block. According to an essential characteristic of the invention, the first means are adapted to generate the prediction block from at least one block of image data of the base layer, called the corresponding block, and at least one block of data. image of the adjacent enhancement layer spatially of the current block, said neighboring block, the corresponding block having been previously coded and reconstructed by the first coding module and the neighboring block having been previously coded and reconstructed by the second coding module.

  The invention further relates to a method of decoding a portion of a bit stream representative of a sequence of images in the form of a base layer and at least one enhancement layer. for the purpose of reconstructing an image data block of the enhancement layer, said current block. The decoding method comprises the following steps: generating, for the current block, an image data prediction block; reconstruct, for the current block, a block of residues from a second part of the representative bitstream of the residue block; and reconstructing the current block from the prediction block and the reconstructed residue block. According to a particularly advantageous characteristic, the prediction block is generated from at least one block of image data of the base layer, called the corresponding block, and from at least one image data block of the neighboring enhancement layer. spatially of the current block, said neighboring block, the corresponding block and the neighboring block having been previously reconstructed.

  The invention further relates to a device for decoding a bitstream representative of a sequence of images in the form of a base layer and at least one enhancement layer. This device comprises a first decoding module capable of reconstructing image data blocks of the base layer and a second decoding module capable of reconstructing image data blocks of the enhancement layer. The second decoding module comprises: first means for generating, for an image data block of the improvement layer, said current block, an image data prediction block; second means for reconstructing, for the current block, a block of 10 residues from a second part of the bitstream representative of the residue block; and third means for reconstructing the current block from the prediction block and the reconstructed block of residues. According to a particularly advantageous characteristic, the first means 15 are adapted to generate the prediction block from at least one block of image data of the base layer, said corresponding block, and at least one block of image data of the enhancement layer spatially neighbor of the current block, said neighboring block, the corresponding block having been previously reconstructed by the first decoding module and the neighboring block having been previously reconstructed by the second decoding module.

  The invention relates to a coded data stream representative of a sequence of images in the form of a base layer and at least one improvement layer. The train includes a first bit data associated with an image slice of the enhancement layer formed of image data blocks. According to one characteristic of the invention, the first bit data takes a first value if the blocks of the slice are predicted from at least one image data block of the previously reconstructed base layer and from at least one image data block of the adjacent enhancement layer spatially of the current block, said neighbor block, previously reconstructed and a second value otherwise. According to a particular characteristic, if the first binary data takes the first value, a second binary data item is associated with each block of the slice, the second binary data item takes a predefined value so that the value can identify for the block of the slice, the at least one neighboring block from which the slice block is predicted.

  4. Lists of the Figures The invention will be better understood and illustrated by means of examples of advantageous embodiments and implementations, in no way limiting, with reference to the appended figures in which: FIG. 1 illustrates according to the state of the art; a coding device, in scalable form, of a sequence of images; FIG. 2 represents a block MBEL of image data of the enhancement layer and blocks A, B, C and D spatially adjacent to said MBEL block of image data as well as BBL blocks corresponding to said MBEL block; FIG. 3 illustrates a method of coding an MBEL block of image data of the improvement layer according to the invention; FIG. 4 illustrates a horizontal directional propagation process according to the invention; FIG. 5 illustrates a vertical directional propagation process according to the invention; FIG. 6 illustrates a diagonal directional propagation process to the right according to the invention; FIG. 7 illustrates a diagonal directional propagation process to the left according to the invention; FIG. 8 illustrates, according to the invention, a method for reconstructing an MBEL block of image data of the improvement layer from a bit stream; FIG. 9 illustrates, according to the invention, a device for coding a sequence of images in scalable form; and FIG. 10 illustrates, according to the invention, a device for decoding a coded image sequence in scalable form;

  5. DETAILED DESCRIPTION OF THE INVENTION With reference to FIG. 3, the invention relates to a method of coding an MBEL image data block with a view to its use by a method of scalable coding of a sequence of image data. presenting in the form of a base layer and at least one enhancement layer. The MBEL image data block is a block of the EL layer. The coding method according to the invention is suitable for coding the MBEL block in conventional intra mode or inter-conventional mode. It is also adapted to code the MBEL block in inter-layer mode from one or more corresponding BBL blocks of the BL layer according to for example the method described in the context of the SVC scalable video coding standard. In the SVC case, if the inter-layer coding mode is selected and if the corresponding BBL blocks are intra-coded, ie spatially predicted, then the MBEL block is coded in inter-layer mode with interlayer prediction of image data texture, ie luminance and chrominance. On the other hand, if the corresponding BBL blocks are encoded in inter mode, then the MBEL block is coded in inter-layer mode with inter-layer prediction of residual image data, themselves obtained for example by temporal prediction. If the corresponding BBL blocks are coded in inter mode for some and in intra mode for others then the MBEL block is coded in inter-layer mode with inter-layer prediction in part of residual image data (from the image data of residues of the corresponding BBL blocks encoded in inter mode) and partly of texture image data (from the texture image data of the corresponding BBL blocks encoded in intra mode). According to an essential characteristic of the invention, new inter-layer prediction modes are defined which are added to the conventional inter-layer prediction mode for example as defined in SVC. These new inter-layer prediction modes make it possible to predict the MBEL block from one or more blocks of corresponding image data in the previously reconstructed BL layer, denoted BBL and one or more blocks of residues denoted Are Brec Cr. , res ec and Drec previously res res reconstructed and associated with blocks A, B, C respectively D spatially adjacent to the block MBEL as illustrated in FIG. 2. In the particular case where a block spatially adjacent to the block MBEL, ie the block A, B, D-neck, is coded in inter-layer mode with inter-layer prediction of residue image data, the corresponding residue block, ie Ares, Brel, Cres respectively DreS comprises the image data of residues obtained during the temporal prediction and not the final residue image data, ie those obtained at the end of the inter-layer prediction itself. In this particular case, the residue block Ares, Bres, Cres respectively Dres corresponds to the pixel-to-pixel sum of the final residue image data of this block and the image data of the block MBBP constructed from BBL blocks of the BL layer. corresponding to A, B, C respectively D.

  According to a particular embodiment, two new inter-layer prediction modes are defined: an inter-layer mode with horizontal spatial prediction and an inter-layer mode with vertical spatial prediction. These 2 modes are defined for luminance image data, they can be extended directly to the case of chrominance image data, or residual image data in the case in particular where the corresponding BBL blocks are encoded in inter mode. Let us note MBpred the prediction block used to predict the MBEL block and MBpred [x, y] the image data value, ie luminance, chrominance or residue, associated with the coordinate pixel (x, y) in the block, x indicating the horizontal position of the pixel in the block and y the vertical position. Note also MBBP [x, y] the image data value associated with the coordinate pixel (x, y) in the MBBP block, said block being conventionally constructed from the reconstructed BBL blocks of the BL layer corresponding to the MBEL block. The pixel at the top left of a block of pixels has coordinates (0, 0) and the pixel at the bottom right has coordinates (N-1, N-1), where N is the size of the block, a coordinate pixel (x, y) being located in column x and line y of the block.

  Let us denote pred_mode, the prediction mode previously determined on the basis of a predetermined criterion, for example of the rate-distortion type, in the set of inter-layer prediction modes.

  When the classical prediction mode, pred_mode = 0, is selected then MBpred [x, y] = MBBP [x, y]. When the inter-layer mode with horizontal spatial prediction, pred_mode = 1, is selected then the MBEL block is predicted using the MBpred block which is built in a step E70 from the MBBP block and the Ares residue block. . When the inter-layer mode with vertical spatial prediction, pred_mode = 2, is selected then the MBEL block is predicted using the MBpred block which is built during a step E70 from the MBBP block and the Cres residue block. . In a step E72, the prediction block MBpred is subtracted pixel by pixel from the image data block MBEL. This step E72 thus generates a residue block denoted MBELIdus which is then transformed, quantized and encoded during a step E74. Step E74 generates a bit stream. According to the invention, if the MBEL block is coded in inter-layer mode with horizontal spatial prediction (pred_mode = 1), the MBpred block is constructed in the following way: MBpred [x, y] = MBBi [x, y] + whor (m A) * MB r [x, y], where x, y = 0..15 where: - MB LoR [x, y] is a spatial prediction block obtained from the reconstructed Ares residue block associated with Block A located to the left of the MBEL block as shown in Figure 2; - whor (mA) is a weighting factor that is predefined according to the coding mode of A and prediction mode pred_mode. If the MBEL block is coded in inter-layer mode with vertical spatial prediction (pred_mode = 2) then the MBpred block is constructed in the following way: MBpred [x, y] = MBBi [x, y] + wverr (m C) * MBELRT [x, y], where x, y = 0..15 where: - MB LoR [x, y] is a spatial prediction block obtained from the reconstructed Cres residue block associated with block C located above the MBEL block as shown in Figure 2; - wVert (mC) is a weighting factor that is predefined according to the coding mode of C and the pred_mode prediction mode.

  The blocks MB 1oR [x, y] and MBEj T [x, y] are obtained by directional propagation of sub-blocks of the residue blocks Ares and Cres of size m by m. An example of horizontal propagation is illustrated in FIG. 4 and an example of vertical propagation is illustrated in FIG. 5. When m = 1, this propagation consists of horizontal respectively vertical propagation of each pixel of the last column respectively last line of the block neighbor A respectively C. If m = 16, block A respectively block C is copied directly. According to one variant, the spatial propagation is carried out with progressive attenuation of the propagated signal. When we are on a pixel near the signal to propagate, the attenuation is low. The further away from the signal to be propagated, the stronger the attenuation. According to an advantageous embodiment, w (m A) and w (m-C) = 0.75 if the neighboring block (ie A or C) and the current block MBEL are predicted according to an inter-layer mode with texture prediction, w (m _ A) and w (m _ C) = 0. 5 if the neighboring block (ie A or C) and the current block MBEL are predicted according to an inter-layer mode with residue prediction, w (m _ A) and w (m _ C) = 0.25 if the neighboring block (ie A or C) and the current block MBEL are predicted according to an inter-layer mode one with residue prediction and the other with texture prediction and w ( m _ A) and w (m _ C) = 0 if one of the blocks is predicted according to a mode that is not inter-layer (ie conventional inter-layer mode). The invention has been described for a particular case where two new inter-layer prediction modes are defined, i.e. one for the vertical spatial direction and one for the horizontal spatial direction. It can be generalized in the case of more than two inter-layer prediction modes by generalizing the notion of spatial direction as illustrated in FIGS. 6 and 7. In these figures, two other spatial prediction modes that can be used with the inter-layer mode are presented. In the general case, the prediction block of the MBEL block is defined as follows: MBpred [x, y] = MBB [x, y] + wd (d, mA, mB, mC, mD) * MBEI [x, y] , where: - MBEL [x, y] is a spatial prediction block obtained from one or more reconstructed residue blocks (ie Arec Brec Cr, res ec and Drec) associated with the remaining blocks A, B, C and D spatially neighbors of the MBEL block as shown in Figure 2; - wd (d, m _ A, m B, m _ C, m _ D) is a weighting coefficient which is predefined according to the coding mode of the neighboring blocks A, B, C and / or D used for the prediction spatial and prediction mode pred_mode.

  These embodiments advantageously make it possible to compensate the loss of the high frequencies in the inter-layer prediction block by adding to it image data and in particular high spatial frequencies, coming from a block spatially adjacent to the current block of the EL layer. Thus, the coding method more efficiently encodes the EL layer, i.e. with fewer bits. In fact, the inter-layer prediction signal is improved, i.e. more frequently rich, which makes it possible to reduce the energy of the residual signal to be coded and thus to reduce the cost of encoding it.

  In the particular case where the BBL blocks corresponding to the MBEL block are coded in inter mode for some and in intra mode for others, the MBBP block is built partly of residue image data and partly of texture image data. The combination of this block with MBEd [x, y] is performed in the same way as for the other cases mentioned above. However, in this case, a specific weighting value wd (d, m _ A, m B, m _ C, m _ D) can be assigned.

  With reference to FIG. 8, the invention relates to a method of decoding a portion of a bit stream T representative of an image sequence in the form of a base layer and at least one an improvement layer for the reconstruction of a block of pixels denoted MBZ. The block MBZ which corresponds to one or more blocks in the base layer, so-called corresponding blocks, belongs to the enhancement layer. The method comprises a step E80 for reconstructing the BBL blocks of base layer image data from a first portion of the bit stream and oversampling them. In a step E81, the MBBP block is constructed from the corresponding BB ~ blocks reconstructed and oversampled in step E80. During a step E82, an MBpred prediction block is constructed from the equations defined for the coding method as a function of the spatial_prediction_direction field decoded during a step E83, the MBBP block and the reconstructed residue blocks Ares, Brel, Cr ,: and D :. The MBpred prediction block is constructed in the same way by the coding method in step E70 and by the decoding method in step E82. In step E84, an MBELSYec residue block corresponding to the MBEL block is also reconstructed from a second part of the bit stream. In a step E85, the prediction block MBpred is added pixel by pixel to the reconstructed MBELSYec residue block. Step E85 reconstructs MBE block ~.

  Referring to Figure 9, the invention relates to a coding device ENC2 of an image sequence in the form of a base layer BL and at least one enhancement layer EL. The modules of the coding device ENC2 identical to those of the coding device ENC1 are identified in FIG. 9 using the same references and are not described further. The encoding device ENC2 comprises the encoding module ENC_BL1, a new coding module ENC_EL2 adapted to code the enhancement layer and the multiplexing module MUX. The encoding module ENC_EL2 is adapted to code blocks of the EL layer according to conventional coding modes (ie inter mode or intra mode), ie by predicting either spatially or temporally said blocks from other blocks of the EL layer. . In addition, in order to reduce the redundancy between the images of the base layer and the images of the enhancement layer, the encoding module ENC_EL2 is also adapted to code blocks of the EL layer from blocks of image data. the layer BL according to an inter-layer coding mode, ie by predicting said image data blocks of the EL layer from image data blocks of the layer BL. In FIG. 9, only the modules of ENC_BL1 and ENC_EL1 necessary for preparing and encoding a block of MBEL image data of the EL layer from at least one image data block of the base layer, ie in a mode of inter-layer prediction, and for encoding said MBEL block. Other modules not shown in this figure (eg motion estimation module, spatial prediction modules, temporal prediction module

  .) and well known to those skilled in the art video coders can code blocks of the EL layer in a temporal prediction mode, said inter mode, conventional (eg bidirectional mode) or in a conventional intra mode ( eg, as defined in AVC) from neighboring blocks A, B, C and / or D. With reference to FIG. 9, the ELC module EL2 comprises, in particular, the coding module 40 and the override module. sampling 20. It further comprises a decision module 15 adapted to select the mode of coding (ie intra, inter, inter-layer) and prediction of the MBEL block according to a predefined criterion for example of the rate-distortion type among a set of modes and in particular those defined in the embodiments described above for the coding method. Finally, it comprises a module 25 adapted to generate a prediction block MBpred according to the prediction mode determined by the module 15 from BBL blocks of the base layer previously coded, then reconstructed by the module ENC BL1 and oversampled by the module 20 and possibly from reconstructed residue blocks associated with blocks A, B, C and D spatially neighboring the MBEL block. The module ENC_EL2 also comprises the subtraction module 30 which subtracts pixel by pixel the prediction block MBpred from the block MB EL, said module generating a block of residues MBE ~ idus which is encoded by the coding module 40. The invention also relates to a bitstream adapted to include information relating to the prediction spatial direction used to generate the prediction block of a MB EL block of the enhancement layer. For this purpose, according to the invention, in the case where for a current block MBEL the inter-layer mode is retained, a first field denoted spatial_prediction_direction is added in the bit stream in order to indicate for the current block MBEL the spatial direction selected for improve / enrich the MBpred inter-layer prediction block of the current MBEL block. For example, this field is 0 if the standard inter-layer mode is applied, 1 if the inter-layer prediction with horizontal spatial prediction is applied and 2 if the inter-layer prediction with vertical spatial prediction is applied. Of course if more than two spatial directions are retained this variable can take more than 3 values. In addition, according to a variant of the invention, a second field is added for example in the header of each slice of image (slice in English) to indicate whether the tool proposed by the invention is authorized. If this field is 1 then this tool is allowed, i.e. the proposed new inter-layer modes with spatial prediction can be used to encode the MBEL blocks. In this case, the spatial_prediction_direction field is encoded in the bitstream for each block of the image slice. If this field is 0 then this tool is not allowed, i.e. the new inter-layer modes with spatial prediction can not be used to encode the MBEL blocks. In these cases no spatial_prediction_direction field is encoded in the bit stream. With reference to FIG. 10, the invention also relates to a decoding device DEC of a bit stream representing a sequence of images, itself being in the form of a base layer and at least one layer improvement. The bit stream received at the input of decoding device DEC is demultiplexed by a demultiplexing module DEMUX in order to generate a bit stream T_BL relating to a base layer and at least one bit stream T EL relating to an enhancement layer. According to one variant, the demultiplexing module DEMUX is external to the decoding device DEC. In addition, the decoding device DEC comprises a first decoding module DEC_BL able to reconstruct at least partially the base layer from the bit stream T_BL. The device DEC also includes a second decoding module DEC_EL able to reconstruct the enhancement layer from the bit stream TEL and possibly image data of the base layer previously reconstructed by the first decoding module DEC_BL module. The second decoding module DEC_EL comprises a module 70 for reconstructing a block of residues MBEL-YeC from a part of the bit stream T_EL. The module 70 is also adapted to decode the spatail_prediction_direction field associated with the reconstructed MBEL-YeC residue block. It further comprises a module 50 for oversampling blocks of the base layer reconstructed by the first DEC_BL decoding module. The module 50 is for example a bilinear interpolation filter. It also comprises a module 60 for constructing an MBpred prediction block according to the prediction mode from the blocks of the base layer oversampled by the module 50 and possibly blocks of residues obtained during the coding of the block (s) A , B, C and D spatially neighbors of the MBEL block. It further comprises a module 80 for adding, pixel by pixel, the MBpred prediction block generated by the module 60 and the MBEL-Yec residue block reconstructed by the module 70. The module 80 reconstructs a block of the improvement layer, noted MBE. ~. According to a particular characteristic of the invention, the image data block of the improvement layer MBEL is a macroblock of size 16 by 16 ... DTD: Of course, the invention is not limited to the embodiments mentioned above. -above. In particular, the invention described in the case of the SVC standard can be applied to another encoding standard defined for encoding a sequence of images in scalable form. In addition, the invention can be extended to any other spatial direction.

Claims (6)

claims   A method of coding an image data block (MBEL), called a current block, of a sequence of images in the form of a base layer and at least one enhancement layer, said current block (MBEL) belonging to said enhancement layer, said method comprising the steps of: generating (E70), for said current block (MBEL), a prediction block (MBpred) of image data; generating (E72) a residue block (MBE ~ Zdus) from the prediction block (MBpred) and said current block (MBEL); and - coding (E74) said residue block (MBE ~ `due); said coding method being characterized in that said prediction block (MBpred) is generated from at least one image data block (BBL) of said base layer, said corresponding block, and at least one block of image data of said enhancement layer spatially adjacent to said current block (MB EL), said neighboring block, said corresponding block and said neighboring block having been previously coded and reconstructed.   An encoding device (ENC2) of an image sequence in the form of a base layer and at least one enhancement layer comprising a first encoding module (ENC_BL1) for encoding blocks of image data of said base layer and a second coding module (ENC EL2) for coding image data blocks of said enhancement layer, said second coding module (ENC_EL2) comprising: - first means (20, 25) for generating, for a block (MBEL) of image data of said enhancement layer, said current block, a prediction block (MBpred) of image data; second means (30) for generating a residue block (MBE ~ Zdus) from the prediction block (MBpred) and said current block (MBEL); and third means (40) for coding said residue block (MelsZd "), said coding device (ENC2) being characterized in that said first means (20, 25) are adapted to generate said prediction block (MBpred) starting from at least one block (BBL) of image data of said base layer, said corresponding block, and at least one image data block of said enhancement layer spatially adjacent to said current block (MBEL), said block neighbor, said corresponding block having been previously coded and reconstructed by said first coding module (ENC_BL1) and said neighboring block having been previously coded and reconstructed by said second coding module (ENC EL2).   A method of decoding a portion of a bitstream representative of a sequence of images in the form of a base layer and at least one enhancement layer for the reconstruction of a block (MBE) of image data of said enhancement layer, said current block, said decoding method comprising the following steps: - generating (E82), for said current block (MBE), a prediction block (MBpred) of image data; reconstructing (E84), for said current block (MBZ), a residue block (MBELSYeC) from a second portion of the representative bitstream of said residue block (MBELSYeO); and - reconstructing (E85) said current block (MBE) from the prediction block (MBpred) and the reconstructed residue block (MBELSYe); said decoding method being characterized in that said prediction block (MBpred) is generated from at least one image data block (BZ) of said base layer, said corresponding block, and at least one block of image data of said enhancement layer spatially adjacent to said current block (MB '), said neighboring block, said corresponding block and said neighboring block having been previously reconstructed (E80, E81, E83).   A decoding device (DEC) for a bitstream representative of an image sequence in the form of a base layer and at least one enhancement layer, said device (DEC) comprising a first decoding module (DEC_BL) able to reconstruct blocks of image data of said base layer and a second decoding module (DEC_EL) able to reconstruct blocks of image data of said enhancement layer, said second decoding module ( DEC_EL) comprising: - first means (50, 60) for generating, for a block of image data (MBEi) of said improvement layer, said current block, a prediction block (MBpred) of image data; second means (70) for reconstructing, for said current block (MBE), a residue block (MBELSYeC) from a second part of the bit stream representative of said residue block (MBELSYeC); and third means (80) for reconstructing said current block (MBE ~) from the prediction block (MBpred) and the reconstructed residue block (MBELSYec); said decoding device (DEC) being characterized in that said first means (50, 60) is adapted to generate said prediction block (MBpred) from at least one image data block (BBL) of said base layer , said corresponding block, and at least one image data block of said enhancement layer spatially adjacent to said current block (MBEL), said neighboring block, said corresponding block having been previously reconstructed by said first decoding module (DEC_BL) and said neighboring block having been previously reconstructed by said second decoding module (DEC_EL).   A coded data stream representative of a sequence of images in the form of a base layer and at least one enhancement layer, said train comprising a first bit data associated with an image slice of said image data block enhancement layer (MBEL), the data stream being characterized in that said first bit data takes a first value if the blocks (MBEL) of said slice are predicted from at least a block (BBL) of image data of said previously reconstructed base layer and from at least one image data block of said spatially adjacent enhancement layer of said current block (MBEL), said neighboring block, previously reconstructed and a second value otherwise.   The data stream according to claim 7, wherein if said first bit data takes said first value, a second bit data is associated with each block of said slice, said second bit data taking a predefined value such that said value permits identifying for said block of said slice, said at least one neighbor block from which said block of said slice is predicted.