Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/10—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding
  • H04N19/102—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the element, parameter or selection affected or controlled by the adaptive coding
  • H04N19/103—Selection of coding mode or of prediction mode
  • H04N19/105—Selection of the reference unit for prediction within a chosen coding or prediction mode, e.g. adaptive choice of position and number of pixels used for prediction
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/50—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using predictive coding
  • H04N19/593—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using predictive coding involving spatial prediction techniques
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/10—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding
  • H04N19/102—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the element, parameter or selection affected or controlled by the adaptive coding
  • H04N19/103—Selection of coding mode or of prediction mode
  • H04N19/11—Selection of coding mode or of prediction mode among a plurality of spatial predictive coding modes
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/10—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding
  • H04N19/102—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the element, parameter or selection affected or controlled by the adaptive coding
  • H04N19/119—Adaptive subdivision aspects, e.g. subdivision of a picture into rectangular or non-rectangular coding blocks
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/10—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding
  • H04N19/169—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the coding unit, i.e. the structural portion or semantic portion of the video signal being the object or the subject of the adaptive coding
  • H04N19/17—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the coding unit, i.e. the structural portion or semantic portion of the video signal being the object or the subject of the adaptive coding the unit being an image region, e.g. an object
  • H04N19/176—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the coding unit, i.e. the structural portion or semantic portion of the video signal being the object or the subject of the adaptive coding the unit being an image region, e.g. an object the region being a block, e.g. a macroblock
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/10—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding
  • H04N19/169—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the coding unit, i.e. the structural portion or semantic portion of the video signal being the object or the subject of the adaptive coding
  • H04N19/182—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the coding unit, i.e. the structural portion or semantic portion of the video signal being the object or the subject of the adaptive coding the unit being a pixel
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/70—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals characterised by syntax aspects related to video coding, e.g. related to compression standards

Definitions

• TITLE METHODS AND DEVICES FOR CODING AND DECODING A DATA FLOW REPRESENTATIVE OF AT LEAST ONE IMAGE
• the field of the invention is that of the coding and decoding of images or sequences of images, and in particular of video streams.
• the invention relates to the compression of images or sequences of images using a block representation of the images.
• the invention can in particular be applied to image or video coding implemented in current or future coders (JPEG, MPEG, H.264, HEVC, etc. and their amendments), and to the corresponding decoding.
• JPEG Joint Photographic Experts Group
• MPEG MPEG
• H.264 High Efficiency Video Coding
• HEVC High Efficiency Video Coding
• Digital images and image sequences take up a lot of memory space, so when transmitting these images, they must be compressed to avoid congestion on the network used for that transmission.
• HEVC compression standard High Efficiency Video Coding, Coding Tools and Specification
• Matthias Wien, Signais and Communication Technology proposes to implement a prediction of pixels of a current image compared to other pixels belonging to the same image (intra prediction) or to a previous or next image (inter prediction).
• intra prediction exploits spatial redundancies within an image.
• the images are cut into blocks of pixels.
• the blocks of pixels are then predicted using information already reconstructed, corresponding to the blocks previously encoded / decoded in the current image according to the order of travel of the blocks in the image.
• the coding of a current block is carried out using a prediction of the current block, called the predictor block, and of a prediction residue or “residual block”, corresponding to a difference between the current block and the predictor block.
• the residual block obtained is then transformed, for example using a DOT-type transform (discrete cosine transform).
• the coefficients of the transformed residual block are then quantized, then encoded by entropy coding and transmitted to the decoder, which can reconstruct the current block by adding this residual block to the predictor block.
• the decoding is done image by image, and for each image, block by block. For each block, the corresponding elements of the stream are read. The inverse quantization and the inverse transformation of the coefficients of the residual block are performed. Then the prediction of the block is calculated to obtain the predictor block, and the current block is reconstructed by adding the prediction (ie the predictor block) to the decoded residual block.
• a DPCM (for Differential Dist Code Modulation) coding technique for coding blocks in Intra mode is inserted in a HEVC encoder.
• One such technique consists in predicting a set of pixels of an intra block by another set of pixels of the same block which have been reconstructed previously.
• a set of pixels of the intra block to be encoded corresponds to a row of the block, or a column or a row and a column and the intra prediction used to predict the set of pixels is one of the intra directional predictions defined in the HEVC standard.
• the synthetic images are likely to contain areas having a very low number of pixel values, also called levels hereafter.
• levels may have only 2 levels: one for the background and one for the foreground, such as black text on a white background.
• the invention improves the state of the art. To this end, it relates to a method for decoding a coded data stream representative of at least one image cut into blocks.
• Such a decoding method comprises, for at least one block of the image, said current block:
• the invention also relates to a method for coding a data stream representative of at least one image cut into blocks.
• a coding method comprises, for at least one block of the image, called the current block:
• a group of pixel values representative of the neighboring pixel values of a block to be coded is determined.
• this group comprises a predetermined number of the most frequent pixel values among the neighboring pixels of the block to be coded.
• this group of values can include intensity values of the layers of the image when the image is represented in layers, for example for synthetic images, or comprising areas with a foreground and a background. delimited, such as black text on a white background.
• the group of values comprises two values representative of the two most frequent values in the neighborhood of the block. When a pixel located in a transition zone is detected, its prediction value is modified to take one of the values of the group thus determined.
• the selection of a value of the group is made as a function of a distance between the prediction value associated with said pixel and determined according to the first prediction mode with respect to the constant pixel values of the group.
• This particular embodiment of the invention makes it possible to easily select a prediction value of the group for a pixel situated in a transition zone and does not require the transmission of additional information to indicate this selection.
• the group comprising a first value and a second value, when a distance between the prediction value associated with said pixel and the first value is less than a distance between the associated prediction value at said pixel and the second value, the value of said selected group is the first value, and the value of said selected group is the second value otherwise.
• the information indicating whether the pixel is predicted according to the second prediction mode is decoded from the data stream or encoded in the data stream only when the pixel prediction residue is different from 0.
• This particular embodiment makes it possible to avoid the coding of the information indicating a prediction according to the second prediction mode when the prediction residue is different from 0.
• the first mode of prediction is used by default to predict the current pixel.
• This particular embodiment of the invention makes it possible to avoid the coding of unnecessary information by the coder. Indeed, at the encoder, when the prediction according to the first prediction mode makes it possible to obtain a zero prediction residue, ie an optimal prediction, the information indicating that the second prediction mode is not used for the current pixel is implicit.
• Such a particular embodiment of the invention can be implemented in the encoder, by a preliminary step of calculating the prediction residue from the prediction resulting from the first prediction mode or else by a step of determining whether the value d the origin of the pixel to be coded is or is not distant from the prediction value resulting from the first prediction mode.
• the determination of a group of constant pixel values for the block from previously decoded pixels is carried out by calculating a histogram of the values of neighboring pixels of the current block and previously reconstructed and the selection of at least two pixel values respectively representative of two most frequent pixel values among the neighboring pixels of the current block.
• a threshold value is determined from at least one value of said group of constant pixel values for the block from previously decoded pixels.
• the second prediction mode is chosen:
• the invention also relates to a device for decoding an encoded data stream representative of at least one image cut into blocks.
• a decoding device comprises a processor configured for, for at least one block of the image, said current block:
• such a decoding device is included in a terminal.
• the invention also relates to a device for coding a data stream representative of at least one image cut into blocks.
• a coding device comprises a processor configured for, for at least one block of the image, said current block:
• such a coding device is included in a terminal, or a server.
• the invention also relates to a data stream representative of at least one image cut into blocks.
• a data stream comprises, for at least one block of the image, said current block, and for each pixel of the current block:
• the decoding method, respectively the encoding method, according to the invention can be implemented in various ways, in particular in wired form or in software form.
• the decoding method, respectively the encoding method is implemented by a computer program.
• the invention also relates to a computer program comprising instructions for implementing the decoding method or the encoding method according to any one of the particular embodiments described above, when said program is executed by a processor.
• Such a program can use any programming language. It can be downloaded from a communications network and / or recorded on a computer readable medium.
• This program can use any programming language, and be in the form of source code, object code, or intermediate code between source code and object code, such as only in a partially compiled form, or in any other desirable form.
• the invention also relates to a recording medium or information medium readable by a computer, and comprising instructions of a computer program as mentioned above.
• the recording media mentioned above can be any entity or device capable of storing the program.
• the medium can include a storage means such as a memory.
• the recording media can correspond to a transmissible medium such as an electrical or optical signal, which can be conveyed via an electrical or optical cable, by radio or by other means.
• the program according to the invention can in particular be downloaded from an Internet type network.
• the recording media can correspond to an integrated circuit in which the program is incorporated, the circuit being adapted to execute or to be used in the execution of the method in question.
• FIG. 1 shows steps of the coding method according to a particular embodiment of the invention.
• FIG. 2A illustrates an example of part of a data stream encoded according to a particular embodiment of the invention.
• FIG. 2B illustrates an example of part of a data stream encoded according to another particular embodiment of the invention.
• FIG. 3A illustrates an example of the position of the neighboring blocks of a current block to determine an intra prediction mode according to a particular embodiment of the invention.
• FIG. 3B illustrates an example of the position of the reference pixels used to predict pixels of a current block according to a particular embodiment of the invention.
• FIG. 4 shows steps of the decoding method according to a particular embodiment of the invention.
• FIG. 5 illustrates examples of blocks comprising content of screen type each having two layers of content, as well as their respective neighborhood in the image according to a particular embodiment of the invention.
• FIG. 6 illustrates an example of a 16x16 block comprising screen type content having two content layers and a transition map showing the transition states of the pixels for this block according to a particular embodiment of the invention.
• FIG. 7 shows the simplified structure of an encoding device suitable for implementing the encoding method according to any one of the particular embodiments of the invention.
• FIG. 8 shows the simplified structure of a decoding device adapted to implement the decoding method according to any one of the particular embodiments of the invention.
• the invention makes it possible to improve a mode of coding a block of an image using a local prediction for pixels of the block located on a transition between two levels of very distinct pixel values.
• a mode of coding a block to be coded using a local prediction allows the use of reference pixels belonging to the block to be coded to predict other pixels of the block to be coded. This prediction mode makes it possible to reduce the prediction residue thanks to the use of pixels of the block which are spatially very close to the pixel to be coded.
• this coding mode introduces a relatively large coding residue when the original pixels are far from their prediction.
• a block to be coded may have strong discontinuities.
• reference pixels belonging to a background can be used to predict pixels of the same block belonging to a foreground, or vice versa.
• the information available in the reference pixels is not adequate for an accurate prediction.
• the pixels located at the border between a background area and a foreground area are hereinafter called transition pixels.
• the invention proposes to derive for a block to be coded information relating to each layer of the image, for example information relating to the foreground and information relating to the background, in the case where only two layers are considered. Additional layers of content can obviously be taken into account, correspondingly increasing the amount of information to be derived. For example, the derivation of such information is to determine a group of constant pixel values for the block.
• this information relating to each layer of the image is derived from a local neighborhood of the block to be coded.
• this information is used with a mechanism for detecting the transition pixels in the block to be coded. This makes it possible to reduce the residual energy of such pixels.
• FIG. 5 illustrates blocks (Bi-bl) comprising content of screen type each presenting two layers of content, as well as their respective neighborhood (Neigh) in the image.
• the local neighborhood of a current block to be encoded contains useful information relating to the level of intensity of the two layers.
• the prediction value for these pixels is corrected using an intensity level of the layer corresponding to that to which the pixel is susceptible. to belong.
• such a mechanism in order to have an optimal prediction for each pixel of the block and a limited bit rate cost, such a mechanism is limited to the pixels satisfying certain conditions.
• three states of the pixel to be predicted can be defined:
• the pixel belongs to a homogeneous region in which the local prediction from neighboring pixels is very efficient, for example it provides a quantized prediction residue of zero.
• the pixel is not a transition pixel. According to an alternative embodiment, this state can be detected implicitly at the decoder,
• the pixel belongs to a region in which the local prediction from neighboring pixels is moderately efficient, for example it provides a weak prediction residual.
• the prediction of the pixel by the correction mechanism cited above is allowed for this pixel, but the correction mechanism is not applied if the residual prediction error is not sufficiently large compared to a determined threshold value. depending on the intensity levels of the layers.
• an indicator is coded specifically to signal the non-use of the correction mechanism,
• the pixel belongs to a region in which the local prediction from neighboring pixels is not efficient, for example it provides a large prediction residue. Prediction of the pixel by the correction mechanism cited above is allowed for this pixel, and a flag is encoded specifically to signal this use.
• FIG. 6 illustrates on the right an example of a 16x16 block comprising light text on a dark background and on the right a transition map for this block showing how the states described above can be assigned to the pixels of the block.
• FIG. 1 shows steps of the coding method according to a particular embodiment of the invention.
• a sequence of images h, l 2 , lisi b is coded in the form of a STR coded data stream according to a particular embodiment of the invention.
• such a coding method is implemented by a coding device as described below in relation to FIG. 7.
• a sequence of images h, l 2 , ..., Iisi b , Nb being the number of images of the sequence to be coded, is supplied at the input of the coding method.
• the encoding method delivers at output an encoded data stream STR representative of the sequence of images supplied as input.
• the coding of the sequence of images 1 ; l 2 , ..., l Nb is made image by image according to a coding order established beforehand and known to the coder.
• the images can be coded in the time order 1 ; l 2 , ..., l Nb or in another order, for example
• an image I to be encoded from the sequence of images ⁇ ⁇ 2 , ..., l Nb is cut into blocks, for example into blocks of size 32 ⁇ 32, or 64 ⁇ 64 pixels or more.
• Such a block can be subdivided into square or rectangular sub-blocks, for example of size 16x16, 8x8, 4x4, 16x8, 8x16, ....
• a first block or sub-block X b to be encoded of the image I is selected according to a direction of travel of the image I, which is predetermined. For example, it can be the first block in the lexicographical order of the image.
• the encoder chooses the encoding mode for encoding the current block X b .
• the encoder selects the coding mode for coding the current block X b from a first coding mode M1 and a second coding mode M2. Additional coding modes (not described here) can be used.
• the first coding mode M1 corresponds to the coding of the current block by intra-classical prediction, for example as defined according to the HEVC standard
• the second coding mode M2 corresponds to a coding mode by prediction said In Loop Residual (ILR) or DPCM described below.
• ILR In Loop Residual
• the principle of the invention can be extended to other types of coding modes for the first coding mode M1.
• the first coding mode can correspond to any type of coding mode using a transformation of the prediction residue (coding by inter-picture prediction, coding by spatial prediction with "template matching" - for model matching - etc. ..).
• the encoder can perform a bit rate / distortion optimization to determine the best encoding mode for encoding the current block.
• additional coding modes distinct from the first and second coding modes can be tested, for example a coding mode in inter mode.
• the encoder simulates the coding of the current block X b according to the different coding modes available in order to determine the bit rate and the distortion associated with each coding mode and select the coding mode offering the best bit rate / distortion compromise, for example according to the function D + ⁇ x R, where R represents the bit rate necessary to code the current block according to the coding mode evaluated, D the distortion measured between the decoded block and the original current block and l a Lagrangian multiplier, for example entered by the user or defined in the encoder.
• step E20 information indicating the coding mode selected for the current block is coded in the data stream STR.
• step E21 for coding the block according to M1. If the current block X b is coded according to the second coding mode M2, the method goes to step E22 for coding the block according to M2.
• the step E21 of coding the block according to the first coding mode M1 is described below.
• the first coding mode corresponds to an intra-classical prediction, such as that defined in the HEVC standard.
• a quantization step 3 ⁇ 4 is determined.
• the quantization step 3 ⁇ 4 can be set by the user, or calculated using a quantization parameter setting a compromise between compression and quality and entered by the user or defined by the encoder.
• a quantization parameter can be the parameter L, used in the rate-distortion cost function D + A x R, where D represents the distortion introduced by the coding and R the rate used to code. This function is used to make coding choices. Conventionally, we are looking for the way to code the image which minimizes this function.
• the quantization parameter can be the QP, corresponding to the quantization parameter conventionally used in the AVC or HEVC standards.
• a prediction of the current block is determined using an intra-classic prediction mode.
• each predicted pixel is calculated only from the decoded pixels resulting from the neighboring blocks (reference pixels) located above the current block, and to the left of the current block. How the pixels are predicted from the reference pixels depends on a prediction mode which is transmitted to the decoder, and which is chosen by the encoder from a predetermined set of known modes of the encoder and the decoder.
• HEVC there are 35 possible prediction modes: 33 modes which interpolate the reference pixels in 33 different angular directions, and 2 other modes: the DC mode in which each pixel of the predicted block is produced from the average of the reference pixels, and PLANAR mode, which performs planar, non-directional interpolation.
• This so-called “intra-classical prediction” approach is well known and also used in the ITU-T H.264 standard (where there are only 9 different modes), as well as in the JEM experimental software available at the internet address ( https://ivet.hhi.fraunhofer.de/). where there are 67 different prediction modes.
• the intra-classical prediction respects the two aspects mentioned above (prediction of the pixels of the block to be coded from pixels of the neighboring blocks and transmission to the decoder of an optimal prediction mode).
• the encoder therefore chooses one of the prediction modes available from the predetermined list of prediction modes.
• One way to choose consists, for example, in evaluating all the prediction modes and in keeping the prediction mode which minimizes a cost function such as, conventionally, the bit rate-distortion cost.
• the prediction mode chosen for the current block is coded from the neighboring blocks of the current block.
• FIG. 3A illustrates an example of the position of neighboring blocks A b and B b of the current block X b to code the prediction mode of the current block X b .
• the intra prediction mode chosen for the current block is coded using the intra prediction modes associated with the neighboring blocks.
• the approach described in the HEVC standard for encoding the prediction mode of the current block can be used.
• such an approach consists in identifying the intra m A prediction mode associated with the block A b located above the current block, and the intra m B prediction mode associated with the block B b located just to the left of the current block.
• MPM for Most Probable Mode
• non-MPM containing the 32 other prediction modes
• syntax elements are transmitted:
• an index in the non-MPM list corresponding to the prediction mode of the current block is coded.
• the prediction residue R for the current block is constructed.
• a predicted block P is constructed as a function of the prediction mode chosen in step E21 1. Then the prediction residue R is obtained by calculating the difference for each pixel, between the predicted block P and the original current block.
• the prediction residue R is transformed into R T.
• a frequency transform is applied to the block of residue R so as to produce the block R T comprising transformed coefficients.
• the transform could be a transform of DCT type for example. It is possible to choose the transform to be used from among a predetermined set of transforms E T and to signal the transform used to the decoder.
• the transformed residue block R T is quantized using for example a scalar quantization of quantization step d. This produces the quantized transformed prediction residue block R TQ .
• the coefficients of the quantized block R TQ are encoded by an entropy coder.
• the entropy coding specified in the HEVC standard can be used.
• the current block is decoded by de-quantizing the coefficients of the quantized block R TQ , then by applying the inverse transform to the de-quantized coefficients to obtain the decoded prediction residue.
• the prediction is then added to the decoded prediction residue in order to reconstruct the current block and to obtain its decoded version.
• the decoded version of the current block can then be used subsequently to spatially predict other neighboring blocks of the image or else to predict blocks of other images by inter-image prediction.
• the step E22 of coding the block according to the second coding mode M2, according to a particular embodiment of the invention, is described below.
• the second coding mode corresponds to so-called ILR prediction coding.
• a quantization step d 2 is determined.
• the quantization step d 2 depends on the same quantization parameter as the quantization step ⁇ which would be determined in step E210 if the current block were coded according to the first coding mode.
• the pixels of the current block can be predicted according to a first prediction mode or a second prediction mode.
• a pixel of the current block is predicted by previously reconstructed pixels of a block neighboring the current block and / or previously processed pixels of the current block itself.
• pixels are chosen which are as close as possible to the pixel to be predicted. For this reason, we speak of a local predictor.
• a pixel of the current block is predicted by a level value of layers selected by a group of values determined from, for example, the neighborhood of the current block.
• a group of constant pixel values for the block is determined from previously decoded pixels.
• Several levels of reconstruction of the current block are determined, for example two, called f and b. These levels are constructed by analyzing the values taken by the reference pixels of the current block, ie the pixels resulting from blocks previously processed and neighboring to the current block.
• There are several techniques for determining the f and b levels Thus, it is possible to calculate the histogram of the values of the reference pixels and to attribute to b the most frequent value and to f the second most frequent value. Another approach consists in identifying the local maxima of the histogram, ie the largest values surrounded by smaller values. The level f is then affected by the greatest local maximum and the level b by the second greatest local maximum.
• thr p- where dyn is the maximum value of the signal.
• the direct neighborhood of the current block is used: for example only the pixels of the column on the left, and of the row above the current block are used.
• more than two values can be determined, by considering the following local maxima of the histogram for example.
• the values f and b thus determined correspond to the values of the group of values used for the second prediction mode.
• a local predictor PL for the pixel considered is determined.
• This local predictor PL corresponds to the predictor obtained according to the first prediction mode.
• the local predictor PL can be determined as follows. If we call X a current pixel to be predicted in the current block, A the pixel located immediately to the left of X, B the pixel located immediately to the left and above X, C the pixel located immediately above X, such that 'illustrated in FIG. 3B showing a current block X b .
• min (A, B) corresponds to the function returning the smallest value between the value of A and the value of B and max (A, B) corresponds to the function returning the largest value between the value of A and the value of B.
• local prediction functions can be used.
• several local prediction functions can be available and the same local prediction function is selected for all the pixels of the current block. For example, an orientation of the texture of the pixels of neighboring blocks previously coded is analyzed. For example, the pixels previously encoded in a neighboring block which are located above or to the left of the current block are analyzed using a Sobel type operator. If it is determined that:
• the prediction value PL (X) associated with the current pixel X of the current block is thus obtained as a function of the location of the pixel in the current block using either pixels outside the block and already reconstructed (and therefore available with their value decoded), either previously reconstructed pixels in the current block, or both. In all cases, the predictor PL uses previously reconstructed pixels.
• FIG. 3B it can be seen that the pixels of the current block located on the first row and / or the first column of the current block will use as reference pixels (to build the prediction value PL (X)) pixels outside the block and already reconstructed (pixels in gray in FIG. 3B) and possibly already reconstructed pixels of the current block.
• the reference pixels used to construct the prediction value PL (X) are located inside the current block.
• the prediction mode is determined from among the first prediction mode and the second prediction mode to be used to predict the current pixel.
• the second prediction mode is chosen when PL (X) ⁇ thr ⁇ X or when PL (X)>thr> X.
• the second prediction mode is chosen: - when the original value X of the pixel is greater than the threshold value thr and the threshold value thr is greater than the prediction value PL (X) associated with the pixel determined according to the first prediction mode, or
• an indicator t indicating that the pixel to be predicted is predicted according to the second prediction mode is positioned at 1 for example, and encoded in the data stream STR for example by entropy coding or transmitted as it is in the stream.
• a value of the group of values determined during step E221 is selected to predict the current pixel.
• the selection of a value of the group is made as a function of the distance between the prediction value associated with said pixel determined according to the first prediction mode with respect to the determined pixel values of the group. during step E221. For example, when the distance between the prediction value PL (X) associated with said pixel according to the first prediction mode and the value b of the group is less than the distance between the prediction value PL (X) associated with said pixel according to the first prediction mode and value f, the selected value is b, and the selected value is f otherwise.
• the L1 or L2 standard can for example be used.
• step E2205 The method then goes to step E2205.
• step E2202 If, during step E2202, it is determined that the current pixel is not predicted according to the second prediction mode, the current pixel is then predicted according to the first prediction mode.
• the prediction value PL (X) associated with the current pixel and obtained according to the first prediction mode is then not modified.
• the prediction value PL (X) may have been obtained either by the first prediction mode or by the second prediction mode.
• Q (X) is the quantized residue associated with X. It is calculated in the spatial domain, ie calculated directly from the difference between the prediction value PL (X) of pixel X and the original value of X. Such a residue quantized Q (X) for pixel X is stored in a quantized prediction residue block R1 Q , which will be encoded later.
• the decoded predicted value P1 (X) of X is calculated by adding to the prediction value PL (X) the de-quantized value of the quantized residue Q (X).
• the decoded predicted value P1 (X) thus makes it possible to predict any pixels which remain to be processed in the current block.
• Such a block P1 constitutes the ILR predictor of the current block (as opposed to the intra-classical predictor).
• the indicator t is also positioned at 0 since the current pixel is not predicted by the second prediction mode, but the flag t is not encoded in the STR data stream.
• This prediction mode will be implicitly deduced at the decoder from the decoded value of the amplitude of the quantized prediction residue Q1 (X).
• the indicator t is coded in the data stream after the coding of the quantized prediction residue Q1 (X).
• the indicator t is positioned at 0, and coded during step E2207 in a systematic manner for each pixel, in the data stream STR, whatever the value of the amplitude a of the prediction residue Q1 (X).
• the determination of the prediction mode from among the first prediction mode and the second mode of prediction. prediction to be used to predict the current pixel can for example be made by comparing a distance measurement between the prediction value provided by the first prediction mode and the original value X of the current pixel and a distance measurement between the value prediction provided by the second prediction mode and the original value X of the current pixel.
• the order of travel of the current block is the lexicographic order, i.e. from left to right, and from top to bottom.
• step E2205 the block of quantified residue R1 Q has been determined.
• This block of quantized residue R1 Q must be coded in order to be transmitted to the decoder.
• the predictor P1 of the current block was also determined.
• the quantized residue block R1 Q is coded in order to transmit it to the decoder. It is possible to use any known approach such as the method described in HEVC to encode the quantized coefficients of a classical prediction residue.
• each quantized prediction residue Q1 (X) of the current block is broken down into a value of amplitude a and an indicator of sign sgn when the amplitude a is distinct from 0.
• the amplitude and sign values of the quantized residue block R1 Q are encoded using an entropy encoder in the STR data stream.
• an additional prediction residue R2 from the ILR predictor obtained for the current block.
• the coding of an additional prediction residue R2 is however optional. It is in fact possible to simply code the current block by its predicted version P1 and the quantized residue R1 Q.
• the following steps correspond to the conventional steps for coding this residue R2.
• the residue R2 is transformed using a frequency transform so as to produce the block of coefficients R2 T.
• the transform can be a DOT type transform for example. It is possible to choose the transform to be used from among a predetermined set of transforms E T2 and to signal the transform used to the decoder. In this case, the set E T2 can be different from the set E T , in order to adapt to the particular statistics of the residue R2.
• the block of coefficients R2 T is quantized, for example using a scalar quantization of quantization steps d. This produces the R2 TQ block.
• the quantization step d can be set by the user. It can also be calculated using the parameter l fixing the compromise between compression and quality and entered by the user or the encoder. For example, the quantization step d can correspond to the quantization step 3 ⁇ 4 or be determined in a manner similar to the latter.
• the coefficients of the quantized block R2 TQ are then transmitted in an encoded manner.
• the encoding specified in the HEVC standard can be used.
• the current block is decoded by de-quantizing the coefficients of the quantized block R2 TQ , then by applying the inverse transform to the de-quantized coefficients to obtain the decoded prediction residue.
• the prediction P1 is then added to the residue of decoded prediction in order to reconstruct the current block and obtain its decoded version X rec .
• the decoded version X rec of the current block can then be used subsequently to spatially predict other neighboring blocks of the image or else to predict blocks of other images by inter-image prediction.
• step E23 it is checked whether the current block is the last block of the image to be processed by the encoding method, taking into account the order of travel defined above. If the current block is not the last block of the image to be processed, during a step E24, the next block of the image to be processed is selected according to the path of the image defined previously and the encoding method goes to step E2, where the selected block becomes the current block to be processed.
• the method passes to the application of post-processing methods to be applied to the reconstructed image during a step E231.
• postprocessing methods can be deblocking filtering and / or an SAO method (for Sample Adaptive Offset) as defined in the HEVC standard.
• the method passes to the coding (step E25) of the next image of the video, if applicable.
• FIGS. 2A and 2B schematically illustrate a part of the data stream resulting from the coding as described above according to various particular embodiments of the invention.
• the data encoded for the pixel X1 are the amplitude value of the quantized prediction residue a (X1), its sign sgn (X1) and the value of the indicator t positioned at 1.
• the data encoded for pixel X2 is the amplitude value of the quantized prediction residue a (X2), its sign sgn (X2) and the value of the indicator t.
• the value of the amplitude of the quantized prediction residue being distinct from 0, the indicator t positioned at 0 is coded explicitly in the stream.
• the encoded data for the pixel X3 is the amplitude value of the quantized prediction residue a (X3) which is zero.
• the value of the amplitude of the quantized prediction residue is distinct from 0, the indicator t positioned at 0 is then not coded explicitly in the stream and will be implicitly deduced at the decoder.
• the data encoded for the pixel X1 are the amplitude value of the quantized prediction residue a (X1), its sign sgn (X1) and the value of the indicator t positioned at 1.
• the data encoded for the pixel X2 are the amplitude value of the quantized prediction residue a (X2), its sign sgn (X2) and the value of the indicator t positioned at 0.
• the data encoded for the pixel X3 are the amplitude value of the quantized prediction residue a (X3) which is zero, and the indicator t positioned at 0.
• FIG. 4 presents steps of the method of decoding a STR of encoded data representative of a sequence of images I ; l 2 , ..., l Nb to be decoded according to a particular embodiment of the invention.
• the STR data stream has been generated via the encoding method presented in relation to FIG. 1.
• the STR data stream is supplied at the input of a decoding device DEC, as described in relation to FIG. 8 .
• the decoding method proceeds to decoding the stream image by image and each image is decoded block by block.
• an image I to be decoded, is subdivided into blocks.
• Each block will undergo a decoding operation consisting of a series of steps which are detailed below.
• the blocks can be the same size or different sizes.
• a first block or sub-block X b to be decoded of the image I is selected as the current block according to a direction of travel of the image I, which is predetermined. For example, it can be the first block in the lexicographical order of the image.
• a step E42 information indicating a coding mode for the current block is read from the data stream STR.
• this information indicates whether the current block is coded according to a first coding mode M1 or according to a second coding mode M2.
• the first coding mode M1 corresponds to the coding of the current block by intra-classical prediction, for example as defined according to the HEVC standard
• the second coding mode M2 corresponds to coding by In Loop prediction Residual (ILR).
• ILR In Loop prediction Residual
• the information read from the STR stream can also indicate the use of other coding modes to encode the current block (not described here).
• a quantization step 3 ⁇ 4 is determined.
• the quantization step 3 ⁇ 4 is determined from a quantization parameter QP transmitted in the STR data stream or in a manner similar to what was done to the encoder.
• the quantization parameter QP can be the quantization parameter conventionally used in the AVC or HEVC standards.
• the prediction mode used to encode the current block is decoded from the neighboring blocks. For this, like what was done at the encoder, the intra prediction mode chosen for the current block is decoded, using the intra prediction modes associated with the neighboring blocks of the current block.
• an index in the non-MPM list corresponding to the prediction mode of the current block is read.
• the binary indicator and the index of the prediction mode are therefore read for the current block from the data stream STR, to decode the intra prediction mode of the current block.
• the decoder constructs a predicted block P for the current block from the decoded prediction mode.
• the decoder decodes the coefficients of the quantized block R TQ from the data stream STR, for example by using the decoding specified in the HEVC standard.
• the decoded block R TQ is de-quantized, for example using a scalar de-quantization of quantization steps This produces the block of dequantized coefficients R QD
• an inverse frequency transform is applied to the block of de-quantized coefficients R TQD so as to produce the block of decoded prediction residue R TQD I.
• the transform may be a transform of inverse DCT type for example. It is possible to choose the transform to be used from among a predetermined set of transforms E Ti by decoding an indicator from the data stream STR.
• the step E44 of decoding the current block is described below when the current block is coded according to the second coding mode M2.
• the quantization step d 2 is determined, in a manner similar to what was done at the encoder.
• the pixels of the current block can be predicted according to the first prediction mode or the second prediction mode already presented in relation to FIG. 1.
• the group of constant pixel values for the block is determined from previously decoded pixels of the image, in a manner similar to what was done at the encoder. It is considered as for the encoder, that the values of levels f and b have been determined.
• the prediction value of the current pixel according to the first prediction mode is determined.
• the same local predictor PL is used as that used at the encoder.
• the local predictor PL is determined in an identical manner to what was done at the encoder.
• the quantized residue R1 Q is decoded from the data stream STR. It is possible to use any known approach such as the method described in HEVC to decode the quantized coefficients of the classical prediction residue. The amplitude a of the quantized prediction residue Q1 '(X) for the current pixel is then obtained.
• an indicator t indicating whether the current pixel is predicted according to the second mode prediction is implicitly positioned at 0.
• the sign sgn associated with the quantized prediction residue QT (X) is read from the data stream STR.
• the indicator t is coded systematically for each pixel of the current block.
• the value 0 or 1 of the indicator t is read from the data stream STR and the state of the pixel s is positioned accordingly.
• the current pixel is predicted according to the second prediction mode.
• a value of the group of values determined during step E441 is selected and assigned to the prediction value PL (X) associated with the current pixel in order to predict the current pixel in a manner similar to what was done to the encoder. For example, if ⁇ PL (X) - b ⁇ ⁇ PL (X) f
• the current pixel is predicted according to the first prediction mode.
• the prediction value PL (X) of the current pixel determined according to the first prediction mode during step E441 1 is not modified.
• the quantized residue Q1 ′ (X) is de-quantized using the quantization step d 2 , so as to produce the de-quantified residue QD1 (X).
• the prediction residues Q1 (X) of the pixels of the current block are placed in a block of prediction residue R1 Q the de-quantized prediction residues QD1 (X) of the pixels of the current block are placed in a block of prediction residue of -quantified R1 QD, The reconstructed values X 'of the pixels of the current block are placed in a reconstructed block P1.
• the browse order is the lexicographic order (from left to right, then the lines from top to bottom).
• the block P1 comprising the reconstructed values PL (X) + QD1 (X) of each pixel of the current block constitutes here the decoded current block X rec .
• an additional prediction residue has been coded for the current block. It is therefore necessary to decode this additional prediction residue in order to reconstruct the decoded version of the current block X rec .
• this other particular embodiment may or may not be activated by default at the level of the encoder and of the decoder.
• an indicator can be encoded in the data stream with the block level information to indicate for each block encoded according to the ILR encoding mode whether an additional prediction residue is encoded.
• an indicator can be encoded in the data stream with the image level or sequence of images information to indicate for all the blocks of the image or of the sequence of images encoded according to the ILR encoding mode if a additional prediction residue is encoded.
• the coefficients of the quantized prediction residue R2 TQ are decoded from the data stream STR, using means adapted to those used the encoder, for example the means implemented in an HEVC decoder.
• the block of quantized coefficients R2 TQ is de-quantized, for example using a scalar de-quantization of quantization steps This produces the block of de-quantized coefficients R2 TQ D
• an inverse frequency transform is applied to the block R2 TQD so as to produce the decoded prediction residue block R2 TQD I
• the inverse transform may be a transform of inverse DCT type for example.
• the transform to be used from among a predetermined set of transforms E T2 and to decode the information signaling the transform to be used at the decoder.
• the set E T2 is different from the set E T , in order to adapt to the particular statistics of the residue R2.
• the current block is reconstructed by adding the predicted block P1 obtained during step E444 to the decoded prediction residue R2 TQDL
• step E45 it is checked whether the current block is the last block of the image to be processed by the decoding method, taking into account the browsing order defined previously. If the current block is not the last block of the image to be processed, during a step E46, the next block of the image to be processed is selected according to the path of the image defined previously and the decoding method passes to step E42, the selected block becoming the current block to be processed.
• the method passes to the application of post-processing methods to be applied to the reconstructed image during a step E451 if necessary.
• post-processing methods can be deblock filtering and / or an SAO method.
• the method then proceeds to decoding (step E47) of the next image of the video, if applicable.
• FIG. 7 shows the simplified structure of a COD coding device suitable for implementing the coding method according to any one of the particular embodiments of the invention.
• the steps of the coding method are implemented by computer program instructions.
• the coding device COD has the conventional architecture of a computer and comprises in particular a memory MEM, a processing unit UT, equipped for example with a processor PROC, and controlled by the computer program PG stored in MEM memory.
• the computer program PG comprises instructions for implementing the steps of the coding method as described above, when the program is executed by the processor PROC.
• the code instructions of the computer program PG are for example loaded into a RAM memory (not shown) before being executed by the processor PROC.
• the processor PROC of the processing unit UT notably implements the steps of the coding method described above, according to the instructions of the computer program PG.
• FIG. 8 shows the simplified structure of a decoding device DEC suitable for implementing the decoding method according to any one of the particular embodiments of the invention.
• the decoding device DEC has the conventional architecture of a computer and includes in particular a MEMO memory, a UTO processing unit, equipped for example with a PROCO processor, and controlled by the PGO computer program stored in MEMO memory.
• the computer program PGO comprises instructions for implementing the steps of the decoding method as described above, when the program is executed by the processor PROCO.
• the code instructions of the computer program PGO are for example loaded into a RAM memory (not shown) before being executed by the PROCO processor.
• the processor PROCO of the processing unit UTO notably implements the steps of the decoding method described above, according to the instructions of the computer program PGO.

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