Abstract: First, second, and third image planes are obtained from at least one image sensor. The first image plane is formed from light of a first spectral distribution. The second image plane is formed from light of a second spectral distribution. The third image plane is formed from light of a spectral distribution which substantially covers the visible spectrum. First spatial frequency components are generated from the first, second and third image planes. A second spatial frequency component is generated from the third image plane. A color transform is applied to the first spatial frequency components from the first, second, and third image planes to obtain at least first, second and third transformed first spatial frequency image planes. The at least first, second and third transformed first spatial frequency image planes are combined with the second spatial frequency component from the third image plane to form an image.

Abstract: An image reading apparatus includes a light source, an imaging optics system, an image pickup device unit, a memory, and a processor. The imaging optics system condenses scattered light reflected on an object to be imaged to form condensed light as an image. The imaging optics system includes plural cells arranged in a main scanning direction and each of which is an independent imaging optics system. Each of the cells includes a telecentric optics system at the document side. Two rows of cells are arranged in a sub-scanning direction. The cells in the rows are arranged zigzag in the main scanning direction to complement a formed image by the cells in the sub-scanning direction. The image pickup device unit is arranged to correspond to each cell. The processor can form a document image by reconstructing and combining image information stored in the memory into an image.

Abstract: The present invention aims to prevent a problem that an image on a document sheet is erased due to misdetection of a line-shaped noise. A copy machine 1 compares RGB values of a target pixel with averaged RGB values (Step S103). If only one of the RGB values has a difference that is greater than a prescribed value Ref2 (Step S103: YES), the copy machine 1 extracts the target pixel as a line-shaped noise pixel, and moves to a line-shaped noise correction (Step S108) while holding the address of the target pixel in a line-shaped noise address storing area 49b. If two of the RGB values have differences (Step S103: NO, Step S104: YES) and a difference between these two of the RGB values is no greater than a prescribed value Ref3 (Step S105: YES), the copy machine 1 extracts the target pixel as a line-shaped noise pixel, and moves to the line-shaped noise correction (Step S108) while holding the address of the target pixel in the line-shaped noise address storing area 49b.

Abstract: An image display apparatus includes: an image display panel having a two-dimensional matrix with (P×Q) pixels each including first, second and third sub-pixels for displaying respective first, second and third elementary colors, and fourth sub-pixel for displaying a fourth color; and a signal processing section configured to receive first, second and third sub-pixel input signals respectively provided with signal values of x1-(p, q), x2-(p, q) and x3-(p, q), and to output first, second, third and fourth sub-pixel output signals respectively provided with signal values of X1-(p, q), X2-(p, q), X3-(p, q) and X4-(p, q), which used for determining the display gradations of the first, second, third, and fourth sub-pixels, respectively, with regard to a (p, q)th pixel where notations p and q are integers satisfying equations 1?p?P and 1?q?Q.

Abstract: A light panel (115, 215, 403, 503, 513, 603, 605) having a predetermined number of emitted color options and a processor (113, 213) operably coupled to the light panel (115, 215, 403, 503, 513, 603, 605). The processor (113, 213) responds to a first color selection actuation by controlling the light panel (115, 215, 403, 503, 513, 603, 605) to display each of the predetermined emitted light options within different portions of the light panel (115, 215, 403, 503, 513, 603, 605). Thereafter, the processor (113, 213) responds to a second color selection actuation by controlling the light panel (115, 215, 403, 503, 513, 603, 605) to display a selected one of the predetermined emitted light options substantially over the light panel (115, 215, 403, 503, 513, 603, 605), wherein the selected one of the predetermined emitted light options is indicated by the second color selection actuation.

Abstract: Systems and techniques for chromatic distortion reduction. Relative chromatic distortion information for an imaging system may be obtained, where the relative chromatic distortion information indicates relative displacement of a first color signal and a second color signal from a reference color signal in an image. The relative chromatic distortion information may be used to modify image data.

Abstract: Systems and methods using polarized filtering for glare removal to improve the process of scanning documents, particularly bound documents with glossy content, are disclosed. The system may generally include a lighting source for illuminating a document, a lighting source polarizer attached to the lighting source to polarize light therefrom, a camera for capturing images of the document, and a camera polarizer attached to the camera. The camera polarizer and the lighting source polarizer may be positioned relative to each other so as to facilitate blocking light reflections causing glare off of the document resulting from the lighting source and arriving at the camera. The system may include multiple lighting sources, some or all of which may have a lighting source polarizer attached thereto.

Abstract: The image read-out device comprises an integrally formed scanning optical unit in which a light source which emits light toward a document, a plurality of reflective mirrors reflecting the light which is emitted from the light source to the document and then reflected, an image forming lens converging the light reflected by a final reflective mirror which finally reflects the light, among the plurality of mirrors, and a light receiving sensor for receiving the light converged by the image forming lens are integrally mounted on a housing, the integrally formed scanning optical unit moving in a scanning direction and reading out an image of the document, wherein an opening is provided on each of top and bottom surfaces of the housing, and wherein the area of the opening provided on the bottom surface is equal or more than that of the opening provided on the top surface.

Abstract: Methods and systems for displaying full-color three-dimensional imagery are provided. A first color set, having a first color spectrum, is defined to include a first set of LEDs. The first color set is assigned to a first color-coded image perspective. A second color set, having a second color spectrum, is defined to include a second set of LEDs. The second color set is assigned to a second color-coded image perspective. The full-color three-dimensional imagery is caused by activating, alternatively, at least two LEDs of the first color set or the second color set and one LED of a remaining color set and displaying the three-dimensional image based on the first image perspective and the second image perspective.

Abstract: The invention relates to a sheet-fed scanner (300) comprising: an illumination device for emitting a luminous flux covering several spectral bands which is intended to illuminate a sheet (204) to be scanned, a focussing device (150), and a detection module (360) comprising a sensor (164) which comprises a plurality of rows (166, 168, 170) of sensitive elements, each sensitive element being provided to deliver an electrical energy that is proportional to the intensity of the luminous flux received, and each row being provided to have its sensitivity peak for one of said spectral bands, the focussing device being provided to focus, onto each of the rows, part of the luminous flux reflected by said sheet, the sheet-fed scanner (300) being characterised in that the detection module (360) comprises a non-prismatic spectral shift device (305) for shifting each part of the luminous flux thus focussed, parallel to said rows (166, 168, 170), the shift being different for each row (166, 168, 170).

Abstract: The color printing control device outputs color material reduction processed data generated by applying a color material reduction process to each pixel of bitmaps converted to color material colors to be used in printing, when it is judged that the color material reduction printing mode is specified. The color material reduction process includes chroma conversion that reduces chroma and under-color removal/black generation that replaces at least a portion of achromatic components generated by overlaying of a plurality of color materials.

Abstract: A mechanism for mitigating undesired color image breakup artifacts arising in display systems that exploit the principle of field sequential color generation. By suitably reducing the time interval during which image information strikes the moving retina, such that the differential position for the respective red, green, and blue components of the image falling upon the moving retina does not exceed the diameter of a retinal cone or rod, the cause of the breakup is negated and the image becomes unitary as expected: the eye sees the image as if all the components arrived at the same time. The truncation of light emission into shorter time frames necessitates a compensatory increase in imaging light intensity, such that the net amount of photonic flux striking the retina, averaged over time, remains unchanged. The mechanism can be applied to systems with discrete red, green, and blue sources as well as to color-wheel-based systems.

Abstract: A system and method for defringing chromatic aberrations that occur in imaging devices such as scanners. The system comprises shift filters to shift lines in the various color planes together. In addition in each color plane, a spread filter is used to compensate for the unequal point spread functions of each color. Furthermore, the results can be enhanced by filtering in the luminance-chrominance space.

Abstract: An image sensing apparatus having a large depth of focus (DOF) and being compact in size is provided.

Abstract: A 4-line CCD sensor according to one embodiment of the present invention has a monochromic reading line sensor section and a color reading line sensor section. This 4-line CCD sensor is characterized in that amplification factors for amplifiers 1 to 4 are set so that the amplitude of an output signal from the monochromic reading line sensor section is the same as that of each output signal from the color reading line sensor section. This 4-line CCD sensor is characterized in that the amplification factors for the amplifiers 1 to 4 are set so that the amplitude of each output signal from the color reading line sensor section is smaller than that of an output signal from the monochromic reading line sensor section.

Abstract: It is made possible to determine image characteristics in a reading image while the image of an original is being read. A first line sensor (9R2, 9G2, 9B2) is arranged on a board and reads the original image. A second line sensor (9K1) has a larger number of pixels than the first line sensor and is arranged on the board to read the original image earlier than the first line sensor. An image signal processing characteristic control unit (46) uses an output of the second line sensor as a control signal to control the processing characteristic of the image signal read by the first line sensor.

Abstract: The appearance of a color print viewed under UV illumination is predicted using a target comprising color patches each printed using a known coverage of printer colorant(s). In one case, the target is illuminated using a UV light source and an electronic image of the target is captured using a digital camera or the like. In another case, a spectrophotometer is used both with and without a UV cutoff filter to measure the target. The captured image data or the spectrophotometric measurements are used to derive a UV printer characterization model that relates any arbitrary combination of printer colorants to a predicted UV color appearance value. Metameric colorant mixture pairs for visible light and UV light viewing can be determined using the UV model together with a conventional visible light printer characterization model. A visual matching task is used to determine a correction factor for the UV printer characterization model.

Abstract: A system and method for displaying video images in response to each frame of field-sequential video signals. The system comprises a backlight comprising first, second and third primary color light sources. The backlight is operable to emit light for at most 5.67 milliseconds of each frame (on-time), and to emit no light during the remainder of each frame (off-time). During a portion of the on-time, at least two of the primary color light sources are on simultaneously. For another portion of the on-time, the primary color light sources are on sequentially.

Abstract: Carried out are (i) an infrared light scanning process in which light is directed to a document in a state in which a visible light cut filter is provided in an optical path, in which the light is directed from a light source to the document, reflected from the document, and then received by a light receiving element, so that the light receiving element receives the reflected light from the document and prepares image data S1; (ii) a visible light scanning process in which the light is directed to the document in a state in which no visible light cut filter is provided in the optical path, so that the light receiving element receives the reflected light from the document and prepares image data S2; and (iii) a color correction process in which a color of an image in the image data S2 is corrected in accordance with the image data S1 so that an influence of light having a infrared wavelength is removed or reduced from the image data S2.

Abstract: A scanning technique for imaging sites in an array includes illuminating or irradiating sites in lines of the array, and collecting returned radiation from the sites for imaging. The sites are sequentially scanned by means of confocally directed radiation lines from source optics. The orientation of the radiation lines with respect to the lines of sites in the array is such that the distance between nearest edges of sites in adjacent lines is greater than lines through those edges in a direction parallel to the radiation lines used for scanning. The resulting system experiences less crosstalk and a greater ability to distinguish between neighboring sites in resulting images.

Abstract: Disclosed herein is a color adjustment apparatus, including: a color information storage section configured to store color information regarding an arbitrary region designated through a pointer in an editing image region; and a color coordinate explicitly displaying section configured to explicitly display a mark, which specifies color coordinates corresponding to the color information, at a pertaining position on a hue ring or a hue bar chart prepared for color adjustment.

Abstract: A scanner and a method of scanning an image on an original includes an optical sensor having sensor elements for each of three basic colors that is used to generate pixel values of the scanned image. Each pixel value represents an optical density of a pixel of the image and is generated mainly on the basis of a signal of only one of the sensor elements. Each of the sensor elements for each of the basic colors is used to generate pixel values representing substantially different parts of the image.

Abstract: A method and apparatus for rendering image data on a 3D display is disclosed. A first image signal is received and then at least one colour component of the first image signal is rendered in reduced spatial resolution to produce a second image signal. The second image signal is spatial filtered wherein spatial errors and view errors are balanced when reconstructing a full resolution signal for the display.

Abstract: A method of creating a super-resolved color image from multiple lower-resolution color images is provided by combining a data fidelity penalty term, a spatial luminance penalty term, a spatial chrominance penalty term, and an inter-color dependencies penalty term to create an overall cost function. The data fidelity penalty term is an L1 norm penalty term to enforce similarities between raw data and a high-resolution image estimate, the spatial luminance penalty term is to encourage sharp edges in a luminance component to the high-resolution image, the spatial chrominance penalty term is to encourage smoothness in a chrominance component of the high-resolution image, and the inter-color dependencies penalty term is to encourage homogeneity of an edge location and orientation in different color bands. A steepest descent optimization is applied to the overall cost function for minimization by applying a derivative to each color band while the other color bands constant.

Abstract: There is provided a technique to make, in a case where a monochrome image is generated based on a color image, a chromatic image region on the color image distinguishable on the monochrome image. There are included a first image reading unit to acquire monochrome image data by reading an image in monochrome from an original document, a second image reading unit to acquire color image data by reading an image in color from an original document, an extraction image generation unit to generate image data by extracting a chromatic image region in the color image data read by the second image reading unit, and a luminance correction unit to make a correction to increase, based on the image data generated by the extraction image generation unit, luminance of a monochrome signal which is included in the monochrome image data read by the first image reading unit and corresponds to the chromatic image region extracted by the extraction image generation unit.

Abstract: An image sensor for capturing a color image is disclosed having a two-dimensional array having first and second groups of pixels wherein pixels from the first group of pixels have narrower spectral photoresponses than pixels from the second group of pixels and wherein the first group of pixels has individual pixels that have spectral photoresponses that correspond to a set of at least two colors, with the placement of the first and second groups of pixels defining a pattern that has a minimal repeating unit including at least six pixels with at least some rows or columns of the minimal repeating unit composed only of pixels from the second group of pixels, and including ways to combine similarly positioned pixels from at least two adjacent minimal repeating units.

Abstract: An image reading apparatus equipped with an illuminating device having little tint variation. A lamp unit illuminates an original with light, and includes a plurality of white LEDs, and a plurality of auxiliary LEDs that emit lights of different colors and arranged in a manner associated with the white LEDs. A CPU causes auxiliary LEDs to be lighted, so as to correct a color of light emitted from each of the white LEDs. An image reading unit reads the original illuminated by the lamp as an image.

Abstract: If the user specifies a color mode, an image reader previously moves a read head to a position where a first read target position r and a read start position on an original are identical with each other. If the user specifies a monochrome mode, the image reader previously moves the read head to a position where a second read target position and the read start position on an original are identical with each other. After this, an image can be read from the same range without increasing the time required for image read processing.

Abstract: A light emitting element has spectral characteristics in a predetermined optical wavelength range. A photodetecting unit includes a photodetecting element capable of detecting a light in the optical wavelength range and performs an OE conversion of either one of a reflected light and transmitted light from a scanning target. A filter unit is arranged in an optical path from the light emitting element to the photodetecting element via the scanning target and having an optical transmission range within the optical wavelength range and covering a range of variation in the optical wavelength range.

Abstract: An image processing device includes: a component separating unit; a distribution modifying unit; and a component combining unit. The component separating unit separates an image, which is represented by image data obtained by imaging a scene, into component images for a plurality of color components. The distribution modifying unit sets one of the component images for a predetermined color component as a reference component image, sets at least one component image other than the reference component image as at least one non-reference component image, and modifies distribution of pixels for brightness levels in each non-reference component image based on distribution of pixels for brightness levels in the reference component image. The component combining unit combines together the reference component image and the at least one non-reference component image modified by the distribution modifying unit.

Abstract: An image sensing apparatus having a large depth of focus (DOF) and being compact in size is provided.

Abstract: A system and method that provide full color mapping of video images with minimal distortion to the image. A two-dimensional look up table may be used to map a certain number of colors, and for colors that are not represented by entries in the table, the four closest entries to the desired color may be interpolated to provide mapping for the color, thus achieving full color mapping. The method may also provide the ability to map colors in partial bypass and full bypass conditions. In a full bypass condition the color goes through the system unchanged, and the system may be capable of mapping the brightness of the color by interpolating the luminance values of the closest table entries.

Abstract: A method for converting polarized color measured values to unpolarized color measured values or vice versa uses a computer. The conversion is carried out by the computer by using a pair of reference measured values determined in polarized and unpolarized form.

Abstract: An imaging apparatus includes a plurality of color filters arranged in a specific arrangement; a plurality of pixels adjacently arranged in each color filter; an exposure setting section for assigning one of a plurality of exposures to each pixel so as to perform exposure using the plurality of exposures; a readout section for reading out an image signal corresponding to each of the plurality of the exposures from the plurality of the pixels of each color filter; and a synthesizing section for determining an image signal of each color filter, based on the image signals read out by the readout section, and synthesizing the determined image signals of all of the plurality of the color filters, so as to output an image signal for forming an image.

Abstract: A filter circuit has: a first and a second current mirror circuit that are each built with a plurality of transistors and that respectively pass a first and a second mirror current according to a constant current; an input terminal via which an input pulse signal is fed in; a first transistor that, in response to the signal fed in via the input terminal and by using a supply voltage, makes the first current mirror circuit operate; a second transistor that, operating in inverted synchronism with the first transistor, in response to the signal fed in via the input terminal and by using a ground voltage, makes the second current mirror circuit operate; a capacitor that is charged by the first mirror current and that is discharged by the second mirror current; and an output terminal via which a voltage at one end of the capacitor is fed out.

Abstract: A document reading apparatus includes a white LED including an LED and a fluorescent material and configured to illuminate a document reading position with light, a reading unit having a color line sensor and a monochrome line sensor and configured to read an image of a document illuminated with the light emitted from the white LED, and a filter arranged on an optical path between the monochrome line sensor and the document, and wherein the filter is configured to suppress transmission of light at a peak wavelength of the LED so that, regarding an intensity of light to be received on the monochrome line sensor, the intensity of the light at the peak wavelength of the LED is smaller than the intensity of the light at the peak wavelength of the fluorescent material when the light emitted from the LED is received.

Abstract: A method of changing driving sequence to output a charge coupled device signal, the method is applied to a scanner. The scanner has a pixel processor and a charge coupled device. A plurality of charge signals detected by the charge coupled device is sequentially output to the pixel processor according to the driving sequence. In the method of changing the driving sequence to output the charge coupled device signal, a fast driving sequence is provided. The fast driving sequence has a period equal to 1/N of the original driving sequence. According to the fast driving sequence, the charge signal is sent to the pixel processing circuit. The charge signals are sampled by the processing circuit according to a sampling sequence, and the data obtained by sampling is output.

Abstract: A color machine vision system with two or more differently colored light sources and one black and white photoelectric sensor (BW sensor). The light sources are employed to separately illuminate a target object with a different color, e.g., red, green, blue, magenta, yellow, and cyan. The BW sensor senses the reflection of colored light off the target object from each light source. A separate measurement is generated by the BW sensor for the reflected colored light from each light source and stored for further processing to render a color image of the target object. A calibration is performed to enable the BW sensor to sense reflected colored light from the target object in a linear mode, not the non-linear (saturated) mode. Since calibration enables the BW sensor's electronic components to operate (sense reflected primary colored light) in a relatively linear mode, the sensor is relatively accurate and fast in alternatively sensing/measuring reflected primary colored light from each of the light sources.

Abstract: When a monochromatic original is read, a control is effected to transfer a charge accumulated in a monochromatic photodiode array to a rear stage, and not to accumulate charges in respective color photodiode arrays. When a color original is read, a control is effected to transfer charges accumulated in the respective photodiode arrays and not to accumulate a charge in the monochromatic photodiode array.

Abstract: An image reading apparatus includes a color line sensor that converts an image of an original document into an electric signal at first resolution and a monochrome line sensor that converts the image of the original document into an electric signal at second resolution higher than the first resolution. The image reading apparatus further includes an image-quality improving circuit that calculates a correlation between first image data obtained by reading the image of the original document at the first resolution with the color line sensor and second image data obtained by reading the image of the original document at the second resolution with the monochrome line sensor and converts the first image data into third image data having resolution higher than the first resolution on the basis of the calculated correlation.

Abstract: The present invention aims to avoid problems such as not detecting line-shaped noises or erasing images on the sheet by erroneously detecting line-shaped noises. A copy machine 1 refers to a judgment table 50b to determine a color corresponding to values of RGB color components read in Step S101 (Step S102). The copy machine 1 selects thresholds and coring levels corresponding to matched RGB color components (Step S104). The copy machine 1 sets the selected thresholds and coring levels to an image processing unit 48 (Step S106). The copy machine 1 judges whether a difference between RGB color components of a target pixel and its neighboring pixels is greater than the thresholds that has been set in Step S106 (Step S107). If judging affirmatively, the copy machine 1 stores the address of the target pixel as a line-shaped noise candidate pixel into a line-shaped noise address storing area 49b (Step s108), and extract a series of line-shaped noise candidate pixels as line-shaped noise pixels (Step S110).

Abstract: In a method and apparatus for processing an image signal, luminance signals are generated for an object pixel and local pixels. A luminance dispersion value is then generated for the object pixel from the luminance signals of the object and local pixels. A control factor is determined from the luminance dispersion value, and at least one image signal of the object pixel is low-pass filtered according to the control factor.

Abstract: There are provided a framing assisting means for displaying as a moving picture object data as well as a profile of an area that is synthesized with a foreground of selected background data on an LCD 26 in a first magnification, a recording means for storing the object data selected by a shutter instruction in a nonvolatile memory to correlate with the selected background data, and a playing means for displaying as a still picture the object data stored in the nonvolatile memory and the background data correlated with the object data on the LCD 26 by applying a magnification varying process that is used to display the object data on the LCD 26 in a magnification smaller than the first magnification.

Abstract: An image processing apparatus reads out image data stored in an image memory unit, performs size reduction, when the read out image data is color image data, on a plurality of pieces of color component data of the color image data by using different pixel number reducing circuits and different filter circuits, performs size reduction, when the read out image data is monochrome image data, on a plurality of pieces of monochrome image data by using the different pixel number reducing circuits and different filter circuits, and generates reduced-size images for a thumbnail display from the reduced-size image data.

Abstract: The invention provides an image reading apparatus that scans an image from an original document including: a light source that irradiates a light to the original document; a photoelectric conversion element; a driving mechanism that relatively moves either one of the photoelectric conversion element or the original document in a predetermined direction with respect to the other; a detection sensor that detects a vector amount of movement of either one of the photoelectric conversion element or the original document in the predetermined direction with respect to the other so as to output a detection signal for each vector amount of movement that corresponds to a minimum unit of a reading area of the image; and a control unit that executes one cycle of operations each time when the detection signal is outputted from the detection sensor.

Abstract: A 4-line CCD sensor according to one embodiment of the present invention has a monochromic reading line sensor section and a color reading line sensor section. This 4-line CCD sensor is characterized in that amplification factors for amplifiers 1 to 4 are set so that the amplitude of an output signal from the monochromic reading line sensor section is the same as that of each output signal from the color reading line sensor section. This 4-line CCD sensor is characterized in that the amplification factors for the amplifiers 1 to 4 are set so that the amplitude of each output signal from the color reading line sensor section is smaller than that of an output signal from the monochromic reading line sensor section.

Abstract: Embodiments of the present invention comprise systems and methods for generating and applying image tone scale corrections with improved color fidelity.

Abstract: A light source module arranged in an image scanning device having a scanning platform and an image-pickup module for scanning a transparent object is disclosed, The light source module includes a cover, a light source mounted in the cover for emitting light to the scanning platform for scanning a transparent object, a RGB filter mounted between the light source and the scanning platform for filtering off the light into RGB lights, a switching mechanism connected to the RGB filter for being controlled to alternately allow one of RGB lights to be transmitted to the scanning platform, and a transmission mechanism for carrying the light source, the RGB filter, and the switching mechanism to move with the image-pickup module for accomplishing the scanning operation to the transparent object.

Abstract: A multiple-field sensor for a scanner suitable for scanning a document. The scanner includes a multiple-field sensor, an average accumulator, and a block of memory. The multiple-field sensor has a plurality of sensing lines for each color channel. Each sensing line picks up a portion of image signal from the document during scanning. The sensing lines scan the same portion of the document to produce corresponding image signals. The average accumulator averages the image signals obtained from the sensing lines of the same color channel to produce an average image signal. The block of memory is used as a storage area for image signals in general and the average image signal in particular.

Abstract: A four-line CCD sensor is structured by line sensors R, G, B in which color filters are respectively disposed on surfaces of light receiving elements, and a line sensor BK at which no color filter is disposed. Amplitudes of signals which are outputted from the line sensors R, G, B at a time of reading a color document, and an amplitude of a signal which is outputted from the line sensor BK at a time of reading a monochrome document are adjusted so as to be substantially equal to one another. In a case in which a color document is read, outputs of the line sensors R, G, B are selectively provided, and in a case in which a monochrome document is read, output of the line sensor BK is selectively provided.