Abstract: A data translation system and method. This invention provides a reverse approach to implement a M bit input to N bit output cumulative/monotonic transfer function, (where M>N) by a (2**N)×M bit memory instead of the conventional (2**M)×N bit memory. The invention offers substantial circuit size savings without compromising on transfer function resolution and is independent of transfer function mapping algorithms. The M bit memory content of the reverse LUT contains input video group information for each output level and the (2**N) addresses of the reverse LUT represent the corresponding transfer function output levels. This data to address representation of the input to output relationship is exactly opposite to the conventional address to data format. Search and compare methods are employed to locate the input video group that the incoming video belongs to and the associated address of the reverse LUT represents the output.

Abstract: A data translation system and method. This invention provides a reverse approach to implement a M bit input to N bit output cumulative/monotonic transfer function, (where M>N) by a (2**N)×M bit memory instead of the conventional (2**M)×N bit memory. The invention offers substantial circuit size savings without compromising on transfer function resolution and is independent of transfer function mapping algorithms. The M bit memory content of the reverse LUT contains input video group information for each output level and the (2**N) addresses of the reverse LUT represent the corresponding transfer function output levels. This data to address representation of the input to output relationship is exactly opposite to the conventional address to data format. Search and compare methods are employed to locate the input video group that the incoming video belongs to and the associated address of the reverse LUT represents the output.

Abstract: A data translation system and method. This invention provides a reverse approach to implement a M bit input to N bit output cumulative/monotonic transfer function (where M>N) by a (2**N)×M bit memory instead of the conventional (2**M)×N bit memory. The invention offers substantial circuit size savings without compromising on transfer function resolution and is independent of transfer function mapping algorithms. The M bit memory content of the reverse LUT contains input video group information for each output level and the (2**N) addresses of the reverse LUT represent the corresponding transfer function output levels. This data to address representation of the input to output relationship is exactly opposite to the conventional address to data format. Search and compare methods are employed to locate the input video group that the incoming video belongs to and the associated address of the reverse LUT represents the output.

Abstract: A system and method for zooming an image. In the illustrative embodiment, the system includes a memory for receiving first and second frames of image data; a motion detector for detecting motion in said first or said second frame of image data; and an intelligent zoom system for zooming said first or said second image using a first or a second zoom method based on a detection of motion by said motion detector on a pixel by pixel basis. In the illustrative embodiment, the invention is scene-based, it works on a pixel by pixel basis to determine if a pixel is in motion. It performs motion related zoom for pixels that are affected by motion and conducts cross-field zoom for steady pixels to reduce motion artifacts in zoom mode. Motion may be determined by comparing frame-to-frame pixel value variations to fixed motion threshold(s) or by other algorithms. Independent-field zoom refers to using information from one input field to form a zoomed picture in one associated output field.

Abstract: A data translation system and method. This invention provides a reverse approach to implement a M bit input to N bit output cumulative/monotonic transfer function (where M>N) by a (2**N) ×M bit memory instead of the conventional (2**M)×N bit memory. The invention offers substantial circuit size savings without compromising on transfer function resolution and is independent of transfer function mapping algorithms. The M bit memory content of the reverse LUT contains input video group information for each output level and the (2**N) addresses of the reverse LUT represent the corresponding transfer function output levels. This data to address representation of the input to output relationship is exactly opposite to the conventional address to data format. Search and compare methods are employed to locate the input video group that the incoming video belongs to and the associated address of the reverse LUT represents the output.

Abstract: A system and method for zooming an image. In the illustrative embodiment, the system includes a memory for receiving first and second frames of image data; a motion detector for detecting motion in said first or said second frame of image data; and an intelligent zoom system for zooming said first or said second image using a first or a second zoom method based on a detection of motion by said motion detector on a pixel by pixel basis. In the illustrative embodiment, the invention is scene-based, it works on a pixel by pixel bases to determine if a pixel is in motion. It performs motion related zoom for pixels that are affected by motion and conducts cross-field zoom for steady pixels to reduce motion artifacts in zoom mode. Motion may be determined by comparing frame-to-frame pixel value variations to fixed motion threshold(s) or by other algorithms. Independent-field zoom refers to using information from one input field to form a zoomed picture in one associated output field.

Abstract: A method of electronically stabilizing an image in the presence of jitter. The jitter induced error is measured prior to the beginning of each active sampling window signal and the error is computed into a corresponding number of pixel clock signal periods. The jitter is compensated for by advancing or delaying the occurrence of the beginning of each active sampling window signal relative to the transaction edge of the frame reference signal by the number of pixel clock signal periods. The jitter induced error is measured prior to the sampling edge of each active sample signal within each active sampling window signal. The error is converted into a corresponding number of pixel clock signal periods. The occurrence of the sampling edge of each subsequent active sample signal is advanced or delayed by the number of pixel clock signal periods corresponding to the jitter induced error. Thus, the sampling of the image is locked to the measured jitter and the image is stabilized in the presence of the jitter.