Abstract: A method of raster-scan search for multi-region OSD and a system using the same are provided. The multi-region OSD is to be displayed on a screen after an alpha-blending of a mixer. The method includes at least following procedures. First, a global header search is executed in the first memory module for each or a portion of a plurality of search lines so as to determine a blending region and store header addresses of OSD regions in a second memory module. Next, whether there is a dummy region at the search line is determined. In addition, an alpha value for the dummy region, a dummy data of the dummy region and the OSD data of the OSD regions at the search line are transmitted to the mixer.

Abstract: A method of raster-scan search for multi-region OSD and a system using the same are provided. The multi-region OSD is to be displayed on a screen after an alpha-blending of a mixer. The method includes at least following procedures. First, a global header search is executed in the first memory module for each or a portion of a plurality of search lines so as to determine a blending region and store header addresses of OSD regions in a second memory module. Next, whether there is a dummy region at the search line is determined. In addition, an alpha value for the dummy region, a dummy data of the dummy region and the OSD data of the OSD regions at the search line are transmitted to the mixer.

Abstract: An image enhancing system uses a perfect reconstructing filter to process image signals within a specified resolution and enhance the image signals. The image enhancing system includes an image-signal-obtaining unit, a first-signal-group processing unit, a high-pass/low-pass-image obtaining unit, a brightness-adjusting unit, a threshold unit, an amplifying unit, an adder and a normalizing unit. The image-signal-obtaining unit obtains nine image signals from three lines of image signals. The first-signal-group processing unit processes the nine image signals. The high-pass/low-pass-image obtaining unit obtains a high-frequency image signal and a low-frequency image signal. The brightness-adjusting unit adjusts the brightness of the low-frequency image signal. The threshold unit processes the noise of the high-frequency image signal. The amplifying unit amplifies the high-frequency image signal. The adder adds the high-frequency image signal and the low-frequency image signal.

Abstract: An apparatus for video processing includes a video decoder, a storage device and a rotation processing unit. The video decoder is utilized for decoding encoded video data to generate video frame data. The storage device is utilized for storing rotated video frame data. The rotation processing unit, which is coupled between the video decoder and the storage device, is utilized for receiving the video frame data before the video frame data generated from the video decoder are stored into the storage device, generating the rotated video frame data according to the video frame data, and then storing the rotated video frame data into the storage device.

Abstract: A method of encoding and decoding image data by applying an image capturing device includes generating a difference coding group, applying an modified Hadamard transform (MHT) on the difference coding group to generate a corresponding low-frequency parameter and a plurality of corresponding high-frequency parameters, adjusting the low-frequency parameter, adjusting the high-frequency parameters by a quantification factor, decoding the low-frequency parameter, decoding the high-frequency parameters by the quantification factor, and applying an inverse modified Hadamard transform (IMHT) on the low-frequency parameter and the high-frequency parameters to decode the difference coding group.

Abstract: A method for transforming an original image to a new image is provided. The original image includes M rows of original data; the new image includes Q rows of new data. The method first generates a (2i?1)th row and a (2i)th row of intermediate data respectively based on the (2i?1)th row and the (2i)th row of original data. Then, the method generates a (2i+1)th row and a (2i+2)th row of intermediate data respectively based on the (2i+1)th row and the (2i+2)th row of original data. During the process of generating the (2i+1)th row of intermediate data, the (2j?1)th row of new data is simultaneously generated based on the (2i?1)th row and the (2i+1)th row of intermediate data. During the process of generating the (2i+2)th row of intermediate data, the (2j)th row of new data is simultaneously generated based on the (2i)th row and the (2i+2)th row of intermediate data.

Abstract: A variable length decoding apparatus and method for the image format of a digital video camera (DV) is provided for decoding the images of a digital video camera on the PASS2 decoding layer. The apparatus comprises a first register, a second register, a third register and a fourth register for saving a bit stream, a barrel shifter for producing output data with a length of sixteen bits, a bit stream generator for generating the combined bit stream, a programmable logic array for decoding the image by looking up the table, a controller for controlling the decoding process and fixed length decode, and an accumulator for accumulating the bit number of the bit stream that is being decoded. The present apparatus can decode much higher frequency components, and the quality of the decoded image is better and the color of the decoded image is more vivid.

Abstract: An image processing method and a two-dimension discrete cosine transformation device using the same method are provided. The method includes steps of reading an image pixel data block, converting the data of the image pixel data block in the form of a frequency domain, limiting the converted data in the form of the frequency domain into a first predetermined number of bits, rearranging original DC values and original AC values, distributing the number of bits of the original DC values and the original AC values, quantifying the original DC values and the original AC values, and storing the quantified DC values and AC values into a memory. The device using the aforementioned method includes a first one-dimension cosine transformation unit connected to a transformation register further connected to a second one-dimension cosine transformation unit and a multiplier unit for receiving outputs from the second one-dimension cosine transformation unit.

Abstract: A method for transforming an original image to a new image is provided. The original image includes M rows of original data; the new image includes Q rows of new data. The method first generates a (2i?1)th row and a (2i)th row of intermediate data respectively based on the (2i?1)th row and the (2i)th row of original data. Then, the method generates a (2i+1)th row and a (2i+2)th row of intermediate data respectively based on the (2i+1)th row and the (2i+2)th row of original data. During the process of generating the (2i+1)th row of intermediate data, the (2j?1)th row of new data is simultaneously generated based on the (2i?1)th row and the (2i+1)th row of intermediate data. During the process of generating the (2i+2)th row of intermediate data, the (2j)th row of new data is simultaneously generated based on the (2i)th row and the (2i+2)th row of intermediate data.

Abstract: An image enhancing system uses a perfect reconstructing filter to process image signals within a specified resolution and enhance the image signals. The image enhancing system includes an image-signal-obtaining unit, a first-signal-group processing unit, a high-pass/low-pass-image obtaining unit, a brightness-adjusting unit, a threshold unit, an amplifying unit, an adder and a normalizing unit. The image-signal-obtaining unit obtains nine image signals from three lines of image signals. The first-signal-group processing unit processes the nine image signals. The high-pass/low-pass-image obtaining unit obtains a high-frequency image signal and a low-frequency image signal. The brightness-adjusting unit adjusts the brightness of the low-frequency image signal. The threshold unit processes the noise of the high-frequency image signal. The amplifying unit amplifies the high-frequency image signal. The adder adds the high-frequency image signal and the low-frequency image signal.

Abstract: A method of encoding and decoding image data by applying an image capturing device includes generating a difference coding group, applying an modified Hadamard transform (MHT) on the difference coding group to generate a corresponding low-frequency parameter and a plurality of corresponding high-frequency parameters, adjusting the low-frequency parameter, adjusting the high-frequency parameters by a quantification factor, decoding the low-frequency parameter, decoding the high-frequency parameters by the quantification factor, and applying an inverse modified Hadamard transform (IMHT) on the low-frequency parameter and the high-frequency parameters to decode the difference coding group.

Abstract: A variable length decoding apparatus and method for the image format of a digital video camera (DV) is provided for decoding the images of a digital video camera on the PASS2 decoding layer. The apparatus comprises a first register, a second register, a third register and a fourth register for saving a bit stream, a barrel shifter for producing output data with a length of sixteen bits, a bit stream generator for generating the combined bit stream, a programmable logic array for decoding the image by looking up the table, a controller for controlling the decoding process and fixed length decode, and an accumulator for accumulating the bit number of the bit stream that is being decoded. The present apparatus can decode much higher frequency components, and the quality of the decoded image is better and the color of the decoded image is more vivid.

Abstract: An apparatus and method for calculating the reference address of motion compensation of an image is used for calculating the reference address of motion compensation of an image in MPEG4 and DivX format. The apparatus comprises a shifter for logically shifting the motion vector of an image to the right by three bits, a block offset address table for providing the offset address, a motion vector amended look-up table for providing the difference between the value by shifting logically the motion vector of an image to the right by three bits and a verification model and an adder for adding the value by shifting the motion vector of the image to the right by three bits and the block offset address of the image. The apparatus for calculating the reference address of motion compensation of an image simplifies the circuit and gets a correct result.

Abstract: An apparatus and method is provided for calculating the prediction value of the high frequency and low frequency components of a MPEG4 or DivX image format. The apparatus comprises a prediction parameter table, a look-up table parameter calculation circuit, a multiplier, a control circuit, and an adder. The present apparatus uses a simple and low-cost structure to decode more efficiently the prediction value of the high frequency and low frequency components of an image in MPEG4 and DivX format.