Abstract: An electronic device may have a display with touch sensors. One or more shielding layers may be interposed between the display and the touch sensors. The display may include transistors with gate conductors, a first planarization layer formed over the gate conductors, one or more contacts formed in a first source-drain layer within the first planarization layer, a second planarization layer formed on the first planarization layer, one or more data lines formed in a second source-drain layer within the second planarization layer, a third planarization layer formed on the second planarization layer, and a data line shielding structure formed at least partly in a third source-drain layer within the third planarization layer. The data line shielding structure may be a routing line, a blanket layer, a mesh layer formed in one or more metal layers, and/or a data line covering another data line.

Abstract: The present invention relates to an encoding method and decoding method, and a device using the same. The encoding method according to the present invention comprises the steps of: specifying an intra prediction mode for a current block; and scanning a residual signal by intra prediction of the current block, wherein the step of scanning the residual signal can determine a scanning type for a luminance signal and a chroma signal of the current block according to an intra prediction mode for a luminance sample of the current block.

Abstract: A method for coding image information includes generating prediction information by predicting information on a current coding unit, and determining whether the information on the current coding unit is the same as the prediction information. When the information on the current coding unit is the same as the prediction information, a flag indicating that the information on the current coding unit is the same as the prediction information is coded and transmitted. When the information on the current coding unit is not the same as the prediction information, a flag indicating that the information on the current coding unit is not the same as the prediction information and the information on the current coding unit are coded and transmitted.

Abstract: The present invention relates to an image encoding and decoding technique, and more particularly, to an image encoder and decoder using unidirectional prediction. The image encoder includes a dividing unit to divide a macro block into a plurality of sub-blocks, a unidirectional application determining unit to determine whether an identical prediction mode is applied to each of the plurality of sub-blocks, and a prediction mode determining unit to determine a prediction mode with respect to each of the plurality of sub-blocks based on a determined result of the unidirectional application determining unit.

Abstract: The present invention discloses an image decoding method, the method including generating a candidate list including motion information derived from a spatial neighboring block and a temporal neighboring block adjacent to a current block; deriving motion information of the current block using the candidate list; generating a prediction block of the current block using the derived motion information; and updating the derived motion information in a motion information list, wherein the generating of the candidate list is performed in such a manner as to include at least one information of the motion information included in the updated motion information list in a block decoded before the current block.

Abstract: The present invention relates to an apparatus and method for encoding and decoding an image by skip encoding. The image-encoding method by skip encoding, which performs intra-prediction, comprises: performing a filtering operation on the signal which is reconstructed prior to an encoding object signal in an encoding object image; using the filtered reconstructed signal to generate a prediction signal for the encoding object signal; setting the generated prediction signal as a reconstruction signal for the encoding object signal; and not encoding the residual signal which can be generated on the basis of the difference between the encoding object signal and the prediction signal, thereby performing skip encoding on the encoding object signal.

Abstract: According to the present invention, an image encoding apparatus comprises: a motion prediction unit which derives motion information on a current block in the form of the motion information including L0 motion information and L1 motion information; a motion compensation unit which performs a motion compensation for the current block on the basis of at least one of the L0 motion information and L1 motion information so as to generate a prediction block corresponding to the current block; and a restoration block generating unit which generates a restoration block corresponding to the current block based on the prediction block. According to the present invention, image encoding efficiency can be improved.

Abstract: A system-on-Chip (SoC) and a load imbalance detecting method of the same are provided. The SoC includes at least one master, a plurality of slaves, an interconnect, a measurement block, a central controller. The interconnect is configured to connect the at least one master and each of the plurality of slaves. The measurement block is configured to connect each of the plurality of slaves and the interconnect using a channel and to measure a load of each of the plurality of slaves. The central controller is configured to measure a load imbalance among the plurality of channels using the measured load information.

Abstract: A computing system includes a memory device into which a design file for a predetermined intellectual property (IP) and a transactor generating tool are loaded, and a processor configured to execute the transactor generating tool loaded into the memory device. The transactor generating tool executed by the processor extracts port information of the IP from the design file, and generates at least one transactor corresponding to the IP based on the port information.

Abstract: A dynamic voltage and frequency scaling (DVFS) verification method of a system on chip according to an exemplary embodiment of the disclosed subject matter includes extracting, by a DVFS state extraction module, a DVFS state conversion code from a code, analyzing the extracted DVFS state conversion code, and generating a DVFS state value according to a result of the analysis, generating, by a valid state extraction module, valid state values which satisfy an operation voltage condition and an operation frequency condition capable of operating the system on chip, and determining, by a stability determination module, stability of the DVFS state value according to whether or not the DVFS state value is equal to one of the valid state values.

Abstract: A computing system includes a memory device into which a design file for a predetermined intellectual property (IP) and a transactor generating tool are loaded, and a processor configured to execute the transactor generating tool loaded into the memory device. The transactor generating tool executed by the processor extracts port information of the IP from the design file, and generates at least one transactor corresponding to the IP based on the port information.

Abstract: A system-on-Chip (SoC) and a load imbalance detecting method of the same are provided. The SoC includes at least one master, a plurality of slaves, an interconnect, a measurement block, a central controller. The interconnect is configured to connect the at least one master and each of the plurality of slaves. The measurement block is configured to connect each of the plurality of slaves and the interconnect using a channel and to measure a load of each of the plurality of slaves. The central controller is configured to measure a load imbalance among the plurality of channels using the measured load information.