Abstract: A digital printing system having a linear printhead includes corrections for cross-track position errors. A data processing system implements a method for determining a cross-track position function which includes printing a test target including a plurality of alignment marks, automatically analyzing a captured image of the printed test target to determine a measured position for each of the alignment marks, comparing the measured positions for the alignment marks to reference positions to determine measured cross-track position errors, and determining a cross-track position correction function responsive to the measured position errors. The cross-track position correction function specifies cross-track position corrections to be applied as a function of cross-track position. A corrected digital image is determined by resampling the image lines of a digital image responsive to the cross-track position correction function.

Abstract: A method for correcting cross-track position errors in a digital printing system having a linear printhead includes printing a test target including a plurality of alignment marks. A data processing system is used to automatically analyze a captured image of the printed test target to determine a measured position for each of the alignment marks. The measured positions for the alignment marks is compared to reference positions to determine measured cross-track position errors. A cross-track position correction function is determined responsive to the measured position errors, wherein the cross-track position correction function specifies cross-track position corrections to be applied as a function of cross-track position. A corrected digital image is determined by resampling the image lines of a digital image responsive to the cross-track position correction function.

Abstract: A method for correcting cross-track position errors in a digital printing system having a linear printhead includes printing a test target including a plurality of alignment marks. A data processing system is used to automatically analyze a captured image of the printed test target to determine a measured position for each of the alignment marks. The measured positions for the alignment marks is compared to reference positions to determine measured cross-track position errors. A cross-track position correction function is determined responsive to the measured position errors, wherein the cross-track position correction function specifies cross-track position corrections to be applied as a function of cross-track position. A corrected digital image is determined by resampling the image lines of a digital image responsive to the cross-track position correction function.

Abstract: Image descriptions described using an image description language are provided for a plurality of images. Image bitmaps are determined by processing the image descriptions, each image bitmap including an array of image pixels. The image bitmaps are stored in an array of digital storage devices, with different portions of the image bitmaps being stored in different digital storage devices, where an allocation table is used to indicate where each portion is stored. When one of the digital storage devices fails, the allocation table is analyzed to determine which portions of the image bitmaps were stored in the failed digital storage device. The lost portions are re-rendered by processing corresponding portions of the image descriptions, and the re-rendered portions are stored in the array of digital storage devices.

Abstract: Image descriptions described using an image description language are provided for a plurality of images. Image bitmaps are determined by processing the image descriptions, each image bitmap including an array of image pixels. The image bitmaps are stored in an array of digital storage devices, with different portions of the image bitmaps being stored in different digital storage devices, where an allocation table is used to indicate where each portion is stored. When one of the digital storage devices fails, the allocation table is analyzed to determine which portions of the image bitmaps were stored in the failed digital storage device. The lost portions are re-rendered by processing corresponding portions of the image descriptions, and the re-rendered portions are stored in the array of digital storage devices.

Abstract: A system for processing a bit map of pixel data signals representative of a multi-dimensional array of imagery data (e g. alpha-numeric text) for transmission over a facsimile communication channel are compressed by providing a plurality of data compression units, a respective one of which is capable of compressing data supplied to it at a compression rate that is only a fraction of the data rate. The bit map is subsampled by demultiplexing the bit map into sub-arrays of data. The sub-array data is coupled to respective sets of compression units, which executes parallel, two-dimensional compression of the demultiplexed sub-array data.

Abstract: The apparatus and method of the present invention utilizes three scaling functions for bi-tonal digitized image data such as documents. The digitized document resolution (i.e. from a digitizing scanner) may be different from the resolution of an image output device (i.e. laser printer, CRT display, fax machine, etc.). The invention takes in the scanned image data and scales the data to compensate for the resolution mismatch of the output device. Although the invention is intended for document archive applications (such as scanning documents on microfilm), the scaling can be performed on any bi-tonal image.

Abstract: The apparatus and method of the present invention utilizes three scaling functions for bi-tonal digitized image data such as documents. The digitized document resolution (i.e. from a digitizing scanner) may be different from the resolution of an image output device (i.e. laser printer, CRT display, fax machine, etc.). The invention takes in the scanned image data and scales the data to compensate for the resolution mismatch of the output device. Although the invention is intended for document archive applications (such as scanning documents on microfilm), the scaling can be performed on any bi-tonal image.