Abstract: An image processing device includes an acceptance unit which accepts an input of print data; a decision unit which decides whether or not a draw instruction for a two-color image consisting of a background color and a foreground color is contained in the print data accepted by the acceptance unit; and a conversion unit which converts to draw a graphic representing a part of the foreground color in the two-color image for an image drawn area, instead of a draw process in pixel units concerning the two-color image, when the decision unit decides that the draw instruction for the two-color image is contained in the print data.

Abstract: An image processing system includes: an update unit updating color space information indicating a color space by allowing rotational movement of a selected reference color, taking a line connecting a white color to a black color in the color space as a rotation axis, based on adjustment information indicating that hue of at least one reference color is adjusted, which is in a reference color group including plural reference colors of a RGB system and plural reference colors of a CMY system in the color space; and a correction unit correcting an input image signal based on the color space information.

Abstract: What is disclosed is a novel system and method for mapping out-of-gamut colors to a device's gamut to improve image quality in a color document reproduction device involves performing the following. First, an out-of-gamut color xi, which is intended to be mapped to a boundary surface of a color gamut of a color marking device, is selected. A gamut mapping function is also selected. The selected gamut mapping function is intended to be applied to the selected out-of-gamut color point. At least one performance attribute is then selected for the color marking device and a multi-objective cumulative cost JT is determined based upon a combination of costs Jgm and Js. The multi-objective cumulative cost JT is then iteratively driven to a minimum. Once the minimum has been determined, a gamut mapping of the selected out-of-gamut color can then be performed using the minimized multi-objective cumulative cost. Various embodiments are disclosed.

Abstract: An image processing apparatus and an image processing method are provided which are capable of selecting an image to be printed in a user's intended color. The image processing apparatus of the present invention includes: a selecting condition setting unit configured to prepare an image selecting condition depending on set output color in printing; a selection DB specifying unit configured to specify a group of images for image selection based on the image selecting condition; and further an image selecting unit configured to select an image from the specified group of images based on the image selecting condition.

Abstract: Method of determining a color gamut of a predetermined print system, comprising determining ink restrictions of the print system, generating all NP states of the print system, generating a convex hull of area coverages of NPs that do not exceed said ink restrictions, determining which NP states are outside of the convex hull, mapping NP states that are outside of the convex hull onto the convex hull, re-expressing the mapped NP states as area coverages of NPs, and sampling the convex hull in a colorimetrically predetermined way.

Abstract: An advantage of the invention is to provide an image processing apparatus and a medium therefor, which enable shortening of processing time necessary for performing the whole color conversion in the case where only one of LUTs used for the color conversion can be stored in a storage means having a high access rate. In the image processing apparatus, for image data including a plurality of pixels and being a target for a color conversion, when performing the color conversion of the image data, a value of a counter for pictures, which indicates a predicted total number of references to an LUT for pictures, and a value of a counter for texts, which indicates a predicted total number of references to an LUT for texts, are derived.

Abstract: In the case of a text mode, a text LUT is stored by using the number Nt1 of first text grid cells so that the storage size does not exceed the amount of free space of an integrated RAM. In the case of a photograph mode, or in the case of a mixed text-and-photograph mode and special paper being used as paper, a photograph LUT is stored by using the number Np1 of first photograph grid cells so that the storage size does not exceed the amount of free space of the integrated RAM. In the case of a mixed text-and-photograph mode and plain paper being used as paper, the photograph LUT is stored so that the total of storage sizes of the photograph LUT and the text LUT does not exceed the amount of free space of the integrated RAM.

Abstract: A method for extracting step and repeat data from a halftone printing job (200). De-screening a halftone image data on a computer (104) to create a de-screened image. The de-screening (512) is performed on a halftone image data stored in a computer storage (116). The halftone image data contains at least one step and repeat element (208). The de-screened image is scanned (516) to identify unique pixel segments (520). All instances of the found unique pixel segments are used to reconstruct (524) the step and repeat data previously used to create the halftone printing job (200).

Abstract: Digital halftoning processes for producing a halftone image include, for each pixel in the image: indexing a two-dimensional look up table using a position of the pixel, identifying a threshold value for the pixel from the two-dimensional look up table, creating an index that indexes a three-dimensional lookup table using the threshold value and the position of the pixel, and obtaining an output value for the pixel from the three-dimensional look up table via the index. The digital halftoning processes also produce a halftone representation of the image from output values for corresponding pixels.

Abstract: An image processing system, apparatus and method are disclosed for corner enhancing a digital image for rendering on an image output device. According to one exemplary method, pixels associated with corner regions of the digital image are determined using a plurality of vector windows. Subsequently, one or more corner pixels are modified to sharpen the rendering of the digital image on the image output device.

Abstract: In a method to correct a registration error in a printing process, data of first and second images to be printed are subjected to a raster image process via which at least first and second raster graphics are generated. Control data for a print member or two respective print members are formed from the first and the second raster graphics. A recording medium is printed in a first printing process with the control data of the first image. The recording medium is subjected to a treatment via which the recording medium and the first image deform along at least one deformation axis. The recording medium is printed by the print member with the control data of the second image in a second printing process.

Abstract: Aspects of the present invention are related to systems and methods for determining a skew angle associated with a document image. According to a first aspect of the present invention, a rotation vector may be estimated for at least one layer in a vertical-edge buffer and a horizontal-edge buffer. According to a second aspect of the present invention, a rotation vector may be estimated directly from the vertical-edge buffer and the horizontal-edge buffer using a fixed-sized, progressively constrained histogram.

Abstract: An image forming apparatus and a control method to improve image quality. In the image forming apparatus, an edge detecting unit detects an edge pixel from scanned image data, an edge processing unit determines whether the edge pixel is a color edge pixel or a black edge pixel and applies independent edge processing methods to the color edge pixel and the black edge pixel, and a print unit prints the scanned image data using the processed edge pixel.

Abstract: Methods disclosed permit the identification of frame buffer pixels for trapping. In some embodiments, flags associated with pixels in the frame buffer may be used to provide an indication of pixels for trapping. A first bit in a flag associated with a pixel may be set when the pixel is painted. In some embodiments, the method discloses a process for setting the value of a second bit in the flag to determine if the pixel associated with the flag lies on an object boundary. The pixel is identified as a candidate for trapping based on the value of the at least one flag.

Abstract: A computer-readable tint block image generation program that causes a computer to execute a tint block image generation step of generating tint block image data including a latent image portion and a background portion which have different output densities to be reproduced during copying has: a camouflage pattern registration step of inputting and storing in a memory multi-grayscale camouflage pattern data; and a tint block image data generation step of generating a latent image portion image data based on a latent image portion screen for an area corresponding to the latent image portion, and generating a background portion image data based on a background portion screen for an area corresponding to the background portion, for grayscale values of the multi-grayscale camouflage pattern data.

Abstract: What is disclosed is a novel system and method for determining printer performance in terms of image quality defects over a large complex set of conditions based on measurements taken over a small simple set of conditions, thus reducing the amount of time, effort, and wasted paper required to obtain the data. The present system and method effectively utilizes a predictive model that predicts noise measurements of multi-separations from those of single-separation colors and/or a subset of the multi-separations. Because a model is used to comprehend color performance over the entire gamut, the number of patches is reduced. This reduction enables the method to be used within a machine to dynamically characterize the device's image quality performance. Various embodiments have been disclosed.

Abstract: An image acquiring unit reads an original and outputs whole image data of the original including a vertical streak portion corresponding to a location of a foreign material on a read surface of the reading unit. A storing unit stores therein the image data output from the image acquiring unit. A dividing unit defines an edge portion of the image data and divides the image data into vertical-streak-correction subject data and image portion data. A vertical-streak correcting unit performs a correction process on the vertical-streak-correction subject data to compensate a degradation in image quality due to the foreign material.

Abstract: An image forming apparatus having improved installability and operability. The image forming apparatus has an operation unit thereof disposed on an arm extending from the apparatus and pivotable around a support member in substantially the horizontal direction, and has sensors for detecting the pivot position of the operation unit. An initial-screen setting screen determined based on the pivot position of the operation unit detected by the sensors is displayed on the operation unit.

Abstract: What is disclosed is a novel system and method for determining color profiles based upon optimizing output image spatial noise. For each of a number of selected output colors, spatial noise values for a set of device-dependent color specifications that produce the selected output color are iteratively determined. The set of device-dependent color specifications is generated by varying a subset of colorants in the device-dependent color specifications while changing the remaining colorants to maintain the selected output color. The iterative process improves the spatial noise value, as determined by a spatial noise model, of the device-dependent color specifications that correspond to the selected output color. When an optimum spatial noise value is found, the device-dependent color specification having that spatial noise value is selected as the mapping for the selected device-independent color specification. Various embodiments are disclosed.

Abstract: Methods and apparatuses for halftoning an image are provided using a parametrically controlled hexagonal halftone dot shape threshold function that reduces tone reproduction irregularities in the halftoned image which can occur at darker gray levels. The halftoning transforms image data representing contone image pixels into halftoned image data in the form of clustered-dot hexagonal halftone screens for representing halftone dots of a halftoned image. Weight parameters can be used to control the rate at which a respective vertex of a halftone dot approaches a vertex of a neighboring halftone dot in relation to gray level. The hexagonal halftone dot shape threshold function can also control the shape of the sides of the halftone dots.