Abstract: An image display apparatus is coupled to a nonvolatile memory section, and includes an image processing part configured to display an image on a display device, an initial setting circuit, and a control register configured to control respective parts in the image display apparatus. At power-on or start-up of the image display apparatus, the initial setting circuit reads initialization data from the nonvolatile memory section and sets communication mode for communicating with the nonvolatile memory section to the control register. The communication mode is specified by the initialization data. After the initial setting circuit sets the communication mode to the control register, the image processing part reads image data from the nonvolatile memory section by using the communication mode set in the control register and displays an initial image relating to the image data on the display device.

Abstract: In a lossless compression-encoding device, a calculation part calculates differences between different types of pixel data representing the first, second and third color components of an image, and outputs the calculated differences as a plurality of types of difference data. A lossless compression-encoding part performs lossless compression-encoding on each of color component data which include the different types of the pixel data representing the first to third color components and the plurality of the types of the difference data, and outputs a plurality of types of compressed data which correspond to the respective types of the color component data.

Abstract: In a lossless compression-encoding device, a differential coding part calculates a prediction value of data to be compressed, and calculates a prediction error that is a difference between the prediction value and an actual value of the data to be compressed. A prediction error conversion part performs reversal of a sign bit of the prediction error output by the differential coding part in case that the reversal of the sign bit of the prediction error decreases an absolute value of the prediction error. A variable-length coding part performs variable-length coding on the prediction error that has been processed by the prediction error conversion part to generate a variable-length code representing the prediction error, and outputs the variable-length code as compressed data in such a manner that a code length of the compressed data decreases as the absolute value of the prediction error decreases.

Abstract: A compressive coding device is constituted of a coordinates conversion process converting original pixel data of the RGB presentation into pixel data of the YCbCr presentation, an irreversible conversion process, and a reversible compressive coding process. In the irreversible conversion process, the components Cb and Cr of pixel data are thinned out by way of a reduction process and subsequently interpolated based on the component Y of pixel data by way of an expansion process, while some bits of pixel data are reduced by way of a quantization process. The reversible compressive coding process performs a predictive coding process and a variable-length coding process on each pixel data selected in a raster-scanning sequence, thus producing compressive coded data. This makes it possible to decode both reversible compressive coded data and irreversible compressive coded data in units of lines.

Abstract: In a lossless compression-encoding device, a calculation part calculates differences between different types of pixel data representing the first, second and third color components of an image, and outputs the calculated differences as a plurality of types of difference data. A lossless compression-encoding part performs lossless compression-encoding on each of color component data which include the different types of the pixel data representing the first to third color components and the plurality of the types of the difference data, and outputs a plurality of types of compressed data which correspond to the respective types of the color component data.

Abstract: In a lossless compression-encoding device, a differential coding part calculates a prediction value of data to be compressed, and calculates a prediction error that is a difference between the prediction value and an actual value of the data to be compressed. A prediction error conversion part performs reversal of a sign bit of the prediction error output by the differential coding part in case that the reversal of the sign bit of the prediction error decreases an absolute value of the prediction error. A variable-length coding part performs variable-length coding on the prediction error that has been processed by the prediction error conversion part to generate a variable-length code representing the prediction error, and outputs the variable-length code as compressed data in such a manner that a code length of the compressed data decreases as the absolute value of the prediction error decreases.