Abstract: In a halftone module, it is judged whether or not the value “rate” for each pixel is greater than zero (0). In other words, it is judged whether or not the eight-bit input data Iin of each pixel is around a half of the relative density value for a small dot of a corresponding color. If the eight-bit input data Iin of the subject pixel is near to a half of the relative density value for a small dot, noise is added to the threshold values Ta, Tb, and Tc. The noise-added threshold values Ta?, Tb?, and Tc? are used in the comparing process.

Abstract: When a user inputs a print command, a RIP 20 sets a print start flag OFF so that the printing will not be executed. Then, the RIP 20 receives remaining ink amount data from a printer. Further, the RIP predicts the required amount of ink required by the printer to print a desired image based on preview data. The remaining ink amount and the required ink amount for each different colored ink are displayed on a screen. When insufficient ink remains, then a message indicating this is displayed.

Abstract: For each paper type, a plurality of two-dimensional excitation characteristics tables Ti are provided in one to one correspondence with a plurality of colors i. The excitation characteristics table Ti for each color i contains a plurality of sets of excitation-reflectance data Bi (?0, ?) in a two-dimensional matrix form, for a plurality of combinations of incident light wavelengths ? and reflected light wavelengths ?0. The excitation-reflectance data Bi (?0, ?) indicates the ratio of the amount of the reflected light wavelength ?0 generated in response to incidence of the incident light wavelength ?, with respect to the amount of the incident light wavelength ?. Using the two-dimensional excitation characteristics table Ti corresponding to the user's selected paper type and using the spectral radiation characteristics S(?) of the user's selected light source type, Equations (9)-(11) are calculated to create an output profile, and color conversion is performed by using the output profile.

Abstract: An original image is converted into a reduced image, based on which a peripheral average luminance image is obtained through a filtering processing. A Retinex image having a smaller size than the original image is obtained from the peripheral average luminance image and the reduced image. The Retinex image is enlarged, and an output image is generated based on the enlarged Retinex image and the original image.

Abstract: When a logarithmic spiral function curve exists at a position specified by variables, a filter coefficient corresponding to the position is obtained through calculation using Gaussian function stored in a Gaussian function memory, and the filter coefficient is stored in a filter coefficient memory in association with the position specified by the variables. Retinex processing is executed on original image data using the filter coefficients stored in the filter coefficient memory.

Abstract: A plurality of color signals indicative of a plurality of color patterns are processed based on a first distribution curve to distribute the original color signals into color signals for normal ink and color signals for light ink. Then, the plurality of color patterns are printed by the color signals for normal ink and color signals for light ink. Then, the density of each color pattern is detected to produce a density curve. A second distribution curve is produced based on the detected density, the original color signals, and the first distribution curve so that the second distribution curve can attain a properly linearly-changing density curve. By preparing beforehand a plurality of first distribution curves dependently on a variety of usage conditions of the printer, it is possible to use a second distribution curve that is in conformity to the usage condition, under which the printer is desired to be driven, by selecting a distribution curve that corresponds to the usage condition.

Abstract: An apparatus for processing an image, includes: a color information determination unit; and a correction amount setting unit. The color information determination unit classifies a plurality of pixels configuring an image into a plurality of groups according to a brightness thereof, and determines representative color information for each of the groups. The correction amount setting unit sets a correction amount for a white balance correction based on the representative color information determined for at least a part of the groups.

Abstract: After determining a CMYK-to-Lab relationship, a Lab lattice-to-CMYK relationship is determined. The Lab lattice-to-CMYK relationship defines, for each Lab lattice point, a plurality of allowable CMYK data sets. Then, for each Lab lattice point, several allowable CMYK data sets with the largest K value are first selected among the plurality of CMYK data sets. Then, one CMYK data set with the smallest color distance from the subject Lab lattice point is selected among the several allowable CMYK data sets. If the subject Lab lattice point falls within the color reproducible range for the value of K of the selected CMYK data set, the selected CMYK data set is finally determined for the subject Lab lattice point. It is possible to create a lookup table, in which each Lab lattice point falls within the color range of the K value in the corresponding CMYK data set.

Abstract: This specification discloses a computer program product for creating print data utilized by an ink jet printer. The ink jet printer comprises an ink jet head moving in a predetermined direction with respect to a print medium. The computer program product includes instructions for ordering a computer to perform a reading step of reading image data that includes a plurality of first combinations. Each first combination comprises a position and information concerning whether a dot is to be formed at the position. The computer program product includes instructions for ordering the computer to further perform a print data creating step of creating the print data by creating a second combination for each position at which the dot is to be formed. Each second combination comprises the position at which the dot is to be formed and one nozzle randomly selected from the nozzles of the nozzle unit which corresponds to the position.

Abstract: This specification discloses a computer program product manufacturing method. This method is provided with a forming step, a combining step, and a storing step. The forming step instructs the printer to form a dot at a predetermined coordinate. The combining step creates a combination of the predetermined coordinate and a sub-coordinate which is different from the predetermined coordinate. A distance between the predetermined coordinate and a position of a dot formed when the printer tries to form the dot at the sub-coordinate is shorter than the distance between the predetermined coordinate and the position of the dot formed in the forming step. A storing step stores a computer program into a memory medium. The computer program includes instructions for ordering the computer device to perform a choosing step and a converting step. The choosing step chooses a coordinate from bit-mapped data.

Abstract: This specification discloses a device for creating print data utilized by a printer. The print data includes a coordinate at which a dot is to be formed on a print medium by the printer. The print data creating device is provided with a first device and a second device. The first device chooses a first coordinate from bit-mapped data. The bit-mapped data includes a plurality of combinations of the first coordinate and color information. The first device chooses the first coordinate based on the color information being combined with the first coordinate. The second device creates the print data by converting the first coordinate chosen by the first device into at least two second coordinates which are randomly chosen from at least three second coordinates located in the neighborhood of the first coordinate.

Abstract: A profile storing process (S1), a downstream profile preparation process (S2 to S4), a downstream profile judgment process (S6 to S8), an upstream profile preparation process (S6, S7, S9), and a profile judgment process (S11 to S13) are performed. When it is judged in the downstream profile judgment process that the downstream profile has been improperly prepared, or when it is judged in the profile judgment process that at least one of the upstream and downstream profiles has been improperly prepared, then the prepared profile(s) are returned to the initial state of when stored in the profile storing process (S15). Afterward, the series of processes from preparing the downstream profile are again executed.

Abstract: A method for updating profiles is provided. The method involves storing a plurality of successive profiles for an image recording device, and changing at least two of the successive profiles when characteristics of the image recording device change. The profiles are successively used to process image data that is used for recording images on a recording medium by the image recording device.

Abstract: Input image data Ki for the black color component is divided into distribution data Tc, Tn, Ty, and Tk for the four color components C, M, Y, and K. The distribution data Tc, Tm, and Ty for the three color components C, M, and Y is combined to the input image data Ci, Mi, and Yi of the three color components C, M, and Y.

Abstract: If a false edge will possibly occur at a portion in an image where the input pixel value. Iin is equal to the value (Rj+F), where j=N, S, M, or L, the noise value N is generated when the input pixel value Iin is around the value (Rj+F). The noise value N has a value equal to a product of a random number, the value “rate”, and the value “coefficient”. The value “rate” becomes the maximum value (1) when the input pixel value Iin is equal to the value (Rj+F), and becomes zero (0) when the input pixel value Iin is smaller than or equal to the value (Rj+F)—Range and when the input pixel value Iin is greater than or equal to the value (Rj+F)+Range.

Abstract: When the input value becomes close to the medium dot relative density value (Den_M), the large dot threshold value (Thre_L) and medium dot threshold value (Thre_M) become close to each other. It is possible to prevent output values from being converged to the particular medium-dot output value. When the input value becomes close to the small dot relative density value (Den_S), the medium dot threshold value (Thre_M) and the small dot relative density value (Den_S) become close to each other. It is possible to prevent output values from being converged to the particular small-dot output value.

Abstract: During the device link processing, an original lookup table LUT0 is modified into a modified lookup table LUT1 so that achromatic color value sets B2a will be associated with all the achromatic color value sets B1a. Accordingly, during a color conversion processing, by using the modified lookup table LUT1, any input achromatic color value set B1 in (0, 0, 0, K1 in ) will be converted into an output achromatic color value set B2 out (0, 0, 0, K2 out). In this way, the black-print image part in the input image that is reproduced by black ink only by printer A1 will be maintained as a black-print image part and printed by a printer A2 by black ink only. Thus, the black-print information of the input image can be maintained through the color conversion processing.

Abstract: When an image file exists in a folder determined to be the source of a file transfer according to the nth entry of file transfer data, a free space determining unit provided in an image processing device determines whether a work area on the hard disk meets or exceeds a required capacity. If the work area meets or exceeds the required capacity, a FTP client requests an FTP server to transfer the image file. As a result, an image file in a folder that is identified by the nth entry of the file transfer data to be the source of the transfer is transferred to a hot folder identified by the file transfer data to be the destination. Hence, by reliably allocating a work area required for image processing on the hard disk that accommodates the hot folder, it is possible to increase the stability of image processing without stalls and failures in the processing.

Abstract: In order for the user to set new file transfer data, the image file transfer setting unit 30 acquires authentication data from a file transfer data table and displays a list of connections on the display unit 40. Next, the user uses the input unit 42 to select a desired connection from the list and also to input or select a folder 12 to be the transfer source and a hot folder 24 to be the transfer destination. The image file transfer setting unit 30 combines this data as new file transfer data and adds the data to the file transfer data table. In this way, the user can set new file transfer data using authentication data included in preset file transfer data, thereby facilitating the setting of file transfer data and the management of server authentication data.

Abstract: A plurality of color signals indicative of a plurality of color patterns are processed based on a first distribution curve to distribute the original color signals into color signals for normal ink and color signals for light ink. Then, the plurality of color patterns are printed by the color signals for normal ink and color signals for light ink. Then, the density of each color pattern is detected to produce a density curve. A second distribution curve is produced based on the detected density, the original color signals, and the first distribution curve so that the second distribution curve can attain a properly linearly-changing density curve. By preparing beforehand a plurality of first distribution curves dependently on a variety of usage conditions of the printer, it is possible to use a second distribution curve that is in conformity to the usage condition, under which the printer is desired to be driven, by selecting a distribution curve that corresponds to the usage condition.