RU2021125295A - METHOD AND DEVICE FOR ENCODING IMAGE DATA, METHOD AND DEVICE FOR DECODING IMAGE DATA - Google Patents

Claims (25)

1. A method for decoding image data, comprising the steps at which a bitstream containing image data is obtained; parsing the bitstream to obtain information about the partitioning mode of the first level coding tree node, where the root node of the first level coding tree corresponds to one coding tree unit (CTU), and identifying the leaf node of the first level coding tree using the root node of the first level coding tree and a node division mode corresponding to the node division information of the first layer coding tree node; parsing the bitstream to obtain information about the split mode of the second layer coding tree node, where the information about the split mode of the second level coding tree node indicates the use of the horizontal ternary split mode or the vertical ternary split mode to split the first node of the second level code tree, while the root node of the second level coding tree is a leaf node of the first level coding tree; dividing the first node of the second level code tree into three child nodes using a horizontal ternary split mode or a vertical ternary split mode; parse the bitstream to obtain node split mode information of the child node A of the first node, wherein the split node of child node A indicated by the node split mode information for the child node A is not a horizontal binary split node when the first node of the second level code tree is split by a horizontal ternary splitting mode, or not a vertical binary splitting node when the first node of the second level code tree is split by a vertical ternary splitting mode; dividing the child node A into at least two child leaf nodes using the split node of the child node A; decoding a coding block corresponding to a child leaf node B of the at least two child leaf nodes based on the encoded information of the child leaf nodes to obtain an image corresponding to the image data when the child leaf node B does not require further splitting. 2. The decoding method according to claim 1, wherein the region of the picture portion corresponding to the child node A is greater than the sum of the regions of the picture portions corresponding to the three child nodes of the first node. 3. The decoding method according to claim 1, wherein the portion of the image corresponding to the child node B is located in the middle of the portions of the image corresponding to the three child nodes. 4. A method for encoding image data, comprising the steps of determining a coding tree unit (CTU) corresponding to a block of an image to be encoded; dividing the CTU in a node splitting mode corresponding to the first level coding tree to obtain a leaf node of the first level coding tree, wherein the root node of the first level coding tree corresponds to the CTU; dividing the first node of the second level code tree into three child nodes using a horizontal ternary split mode or a vertical ternary split mode, wherein the root node of the second level code tree is a leaf node of the first level code tree; determine the split mode of the child node A of the first node from the set of split mode candidates, wherein the set of split mode candidates does not include the horizontal binary splitting mode when the first node of the second level code tree is split by the horizontal ternary splitting mode, or the vertical binary splitting mode when the first coding node the second-level tree is split by vertical ternary splitting mode; dividing the child node A into at least two leaf child nodes using the split node of the child node A; and encode an encoding module corresponding to a child leaf node B of the at least two child leaf nodes, wherein the child leaf node B does not require further division. 5. The encoding method according to claim 4, wherein the region of the image region corresponding to the child node A is greater than the sum of the regions of the regions of the image corresponding to the three child nodes of the first node. 6. The decoding method according to claim 4, wherein the portion of the picture corresponding to the child node B is located in the middle of the portions of the picture corresponding to the three child nodes. 7. A decoding device comprising a non-volatile memory connected to the processor and storing instructions causing, when executed, the processor to obtain a bitstream containing image data; parsing the bitstream to obtain information about the split mode of the first level coding tree node, where the root node of the first level coding tree corresponds to one coding tree unit (CTU), and identifying the leaf node of the first level coding tree using the root node of the first level coding tree and a node division mode corresponding to the node division information of the first layer coding tree node; parsing the bitstream to obtain information about the split mode of the second layer coding tree node, wherein the split mode information of the second layer coding tree node indicates the use of the horizontal ternary split mode or the vertical ternary split mode to split the first node of the second layer code tree, wherein the root node of the second level coding tree is a leaf node of the first level coding tree; dividing the first node of the second level code tree into three child nodes using a horizontal ternary split mode or a vertical ternary split mode; parsing the bitstream to obtain node split mode information of child A of the first node, wherein the split node of child A indicated by the split mode information for child A is not a horizontal binary split when the first node of the second level code tree is split by a horizontal ternary splitting mode, or not a vertical binary splitting node when the first node of the second level code tree is split by a vertical ternary splitting mode; splitting the child node A into at least two child leaf nodes using the split node of the child node A; decoding a coding block corresponding to a child leaf node B of the at least two child leaf nodes based on the encoded information of the child leaf nodes to obtain an image corresponding to the image data when the child leaf node B does not require further splitting. 8. The decoding apparatus of claim 7, wherein the region of the picture portion corresponding to the child node A is greater than the sum of the regions of the picture portions corresponding to the three child nodes of the first node. 9. The decoding apparatus according to claim 7, wherein the picture portion corresponding to the child node B is located in the middle of the picture portions corresponding to the three child nodes. 10. An encoding device comprising a non-volatile memory connected to the processor and storing instructions causing, when executed, the processor to determine a coding tree unit (CTU) corresponding to a block of an image to be encoded; splitting the CTU in a node splitting mode corresponding to the first level coding tree to obtain a leaf node of the first level coding tree, wherein the root node of the first level coding tree corresponds to the CTU; dividing the first node of the second level code tree into three child nodes using a horizontal ternary split mode or a vertical ternary split mode, wherein the root node of the second level code tree is a leaf node of the first level code tree; determining the split mode of the child node A of the first node from the set of split mode candidates, wherein the set of split mode candidates does not include the horizontal binary split mode when the first node of the second level code tree is split by the horizontal ternary split mode, or the vertical binary split mode when the first the second-level tree is split by vertical ternary splitting mode; splitting the child node A into at least two leaf child nodes using the split node of the child node A; and coding a coding unit corresponding to a child leaf node B of the at least two child leaf nodes, wherein the child leaf node B does not require further splitting. 11. The encoding apparatus according to claim 10, wherein the region of the image region corresponding to the child node A is greater than the sum of the regions of the regions of the image corresponding to the three child nodes of the first node. 12. The coding apparatus of claim 10, wherein the image portion corresponding to the child node B is located in the middle of the image areas corresponding to the three child nodes. 13. A method for decoding image data, comprising the steps of obtaining a bitstream containing image data; parsing the bitstream to obtain information about the split mode of the code tree node, the information about the split mode of the code tree node indicating the use of the horizontal ternary split mode or the vertical ternary split mode to split the first code tree node; dividing the first node of the code tree into three child nodes using a horizontal ternary split mode or a vertical ternary split mode; parse the bitstream to obtain node split mode information of the child node A of the first node, wherein the split node of child node A indicated by the node split mode information for the child node A is not a horizontal binary split node when the first node of the second level code tree is split by a horizontal ternary splitting mode, or not a vertical binary splitting node when the first node of the second level code tree is split by a vertical ternary splitting mode; dividing the child node A into at least two child leaf nodes using the split node of the child node A; decoding a coding block corresponding to a child leaf node B of the at least two child leaf nodes based on the encoded information of the child leaf nodes to obtain an image corresponding to the image data when the child leaf node B does not require further splitting. 14. The decoding method according to claim 13, wherein the region of the picture portion corresponding to the child node A is greater than the sum of the regions of the picture portions corresponding to the three child nodes of the first node. 15. The decoding method according to claim 13, wherein the picture portion corresponding to the child node B is located in the middle of the picture portions corresponding to the three child nodes. 16. A decoding device comprising a non-volatile memory connected to the processor and storing instructions causing, when executed, the processor to obtain a bitstream containing image data; parsing the bitstream to obtain information about the split mode of the code tree node, the information about the split mode of the code tree node indicating the use of the horizontal ternary split mode or the vertical ternary split mode to split the first code tree node; dividing the first node of the code tree into three child nodes using a horizontal ternary split mode or a vertical ternary split mode; parsing the bitstream to obtain node split mode information of child A of the first node, wherein the split node of child A indicated by the split mode information for child A is not a horizontal binary split when the first node of the second level code tree is split by a horizontal ternary splitting mode, or not a vertical binary splitting node when the first node of the second level code tree is split by a vertical ternary splitting mode; splitting the child node A into at least two child leaf nodes using the split node of the child node A; decoding a coding block corresponding to a child leaf node B of the at least two child leaf nodes based on the encoded information of the child leaf nodes to obtain an image corresponding to the image data when the child leaf node B does not require further splitting. 17. The decoding apparatus of claim 16, wherein the region of the picture portion corresponding to the child node A is greater than the sum of the regions of the picture portions corresponding to the three child nodes of the first node. 18. The decoding apparatus according to claim 16, wherein the picture portion corresponding to the child node B is located in the middle of the picture portions corresponding to the three child nodes.