Abstract: A CMOS image sensor includes: a plurality of CDS/PGAs (correlating double sampling/programmable gain amplifiers) for processing output signals of pixels corresponding to same colors on different paths; and an offset difference removing part for removing offset difference that occurs when the same color signals are processed on the different paths, wherein the offset difference removing part includes: a dummy pixel array where light is shielded; a unit for reading signals of the dummy pixel array through the CDS/PGAs and storing average offset values for each path; and a signal synthesizing unit for synthesizing the average offset values and signals of an effective pixel array, which are read through the respective CDS/PGAs, and outputting signals of which offset difference is removed.

Abstract: A method and system is for limiting the x-droop effect in the digital image captured with solid state image sensors with a correction mechanism which instead of using only correction values from the same column to which the correction is applied, also takes the neighboring pixels into account to provide an averaged value to aid in the reduction of temporal and fixed noise contributions associated with the readout of a single pixel.

Abstract: A method for generating a deselect mapping for a focal plane array according to one embodiment includes gathering a data set for a focal plane array when exposed to light or radiation from a first known target; analyzing the data set for determining which pixels or subpixels of the focal plane array to add to a deselect mapping; adding the pixels or subpixels to the deselect mapping based on the analysis; and storing the deselect mapping. A method for gathering data using a focal plane array according to another embodiment includes deselecting pixels or subpixels based on a deselect mapping; gathering a data set using pixels or subpixels in a focal plane array that are not deselected upon exposure thereof to light or radiation from a target of interest; and outputting the data set.

Abstract: An image calibration method includes: (a) sensing at least one target pixel of a sensing row from an effective pixel region of an image sensor to generate at least one target pixel value; (b) sensing at least one reference pixel of a shading region in the image sensor to generate a calibration value, wherein the reference pixel and the sensing row do not belong to the same row; and (c) referring to the calibration value to calibrate and output the target pixel value.

Abstract: An image sensor having an array of pixel cells, each including a photo-conversion device. The array has first, second, and third groups of pixel cells. The first group of pixel cells receives light and the second and third groups are shielded from light. Each pixel cell of the second group is configured to output a black reference signal for determining a black level of the array. Each pixel cell of the third group has at least one first transistor coupled to the photo-conversion device, and each transistor coupled to the photo-conversion device has a gate coupled to a power supply voltage.

Abstract: A CMOS image sensor includes an image pixel array, a dark pixel array, data bit liens, reference bit lines, a driver, comparators, and analog-to-digital converter (“ADC”) circuits. The image pixel array generates analog image signals in response to incident light. The dark pixel array generates analog black reference signals for analog black level calibration of the analog image signals. In one embodiment, the data bit lines each coupled to a different column of image pixels of the image pixel array and the reference bit lines each coupled to a different column of black reference pixels within the dark pixel array. The driver is coupled to the reference bit lines to drive an analog black reference signal. The comparators each couple to one of the data bit lines and each coupled to an output of the driver and offset the analog image signals with the analog black reference signals in an analog domain. The ADC circuits each coupled to an output of a comparator.

Abstract: A solid-state image pickup device includes a pixel array, a gain adjusting unit that adjusts a gain of a pixel signal, an A/D conversion unit that performs A/D conversion on an image pickup signal, a plurality of fixed pattern noise detection units that detect a fixed pattern noise from a digital image pickup signal, a selecting unit that selects one output from outputs of the plurality of fixed pattern noise detection units, a fixed pattern noise correction unit that corrects the fixed pattern noise included in the digital image pickup signal, and a control unit that controls the gain adjusting unit setting a plurality of gain values, the control unit controlling the plurality of fixed pattern noise detection units detecting the plurality of fixed pattern noise based on the plurality of gain values and storing a plurality of correction values.

Abstract: A solid-state imaging device includes: a pixel array section having an effective pixel region formed by a plurality of pixels which are disposed in the form of a matrix, each of which includes a photoelectric conversion device and a transistor reading out an electric charge obtained by photoelectric conversion at the photoelectric conversion device, and which are illuminated by light and a light-shielded pixel region formed by a plurality of pixels which are shielded from light; a row scan section selecting and controlling each row of pixels of the pixel array section to output a signal from each of the pixels of the selected row of pixels to a column signal line provided in association with the row of pixels; and an A-D conversion section converting the signal output from the signal line into a digital signal.

Abstract: An image capturing apparatus comprises: an image sensor having an effective pixel area where plural pixels not shield from light are two-dimensionally arranged, and a first optical black area and a second optical black area including pixels shielded from light provided on the both sides of the effective pixel area; and a correction unit to, upon incident of high luminance light on the image sensor, correct an output signal of a pixel between a high luminance portion as a pixel part on which the high luminance light is incident in the effective pixel area and the first optical black area using an output signal of the first optical black area, and correct an output signal of a pixel between the high luminance portion and the second optical black area, using an output signal of the second optical black area.

Abstract: A horizontal evaluation data generation section calculates an average value of pixel signals in a vertical optical black region based on given pixel data in the horizontal optical black region and outputs the calculated average value to an evaluation section. A vertical evaluation data generation section calculates an average value of pixel signals in a vertical optical black region based on given pixel data in the vertical optical black region and outputs the calculated average value to the evaluation section. The evaluation section outputs a gain value according to the difference between the two sent average values to a computing section. A smear information memory stores pixel signals in a line in the vertical optical black region. The computing section multiplies the pixel data stored in the smear information memory by the sent gain value, and subtracts the multiplied pixel data from the pixel data imaged by the CCD.

Abstract: Embodiments of circuits and methods for suppressing row-wise noise in the analog domain in an image sensing device. In one embodiment, a pixel sampling circuit includes a readout circuit that is connected to a plurality of pixels to receive analog signals from the pixels. The pixel sampling circuit also includes a noise correction circuit that provides a reference signal to remove at least a portion of the noise in the analog signals received from the pixels before the analog signals are converted into digital signals.

Abstract: A clamp control method, a clamp correction device, an image sensor, and an electronic apparatus in which high-quality imaging without unnaturalness as a whole can be performed with low power consumption in an image sensor having a large number of pixels.

Abstract: An image pickup apparatus is provided that is capable of obtaining a correction value effective for horizontal noise correction, while suppressing increase in chip area of an image pickup device. The image pickup apparatus includes an image pickup device (101) for converting an object image into electrical signals, and a correcting section for correcting a picked-up image. The image pickup device includes a pixel signal readout circuit (204) for reading out pixel signals from a pixel region on a line-by-line basis via vertical signal lines, a dummy signal readout circuit (209) for reading out dummy signals, and a horizontal transfer circuit (205) for transferring outputs of the pixel signal readout circuit and the dummy signal readout circuit. The correcting section corrects the outputs of the pixel signal readout circuit on a line-by-line basis using the outputs of the dummy signal readout circuit.

Abstract: A solid-state imaging device includes: a pixel array section having an effective pixel region formed by a plurality of pixels which are disposed in the form of a matrix, each of which includes a photoelectric conversion device and a transistor reading out an electric charge obtained by photoelectric conversion at the photoelectric conversion device, and which are illuminated by light and a light-shielded pixel region formed by a plurality of pixels which are shielded from light; a row scan section selecting and controlling each row of pixels of the pixel array section to output a signal from each of the pixels of the selected row of pixels to a column signal line provided in association with the row of pixels; and an A-D conversion section converting the signal output from the signal line into a digital signal.

Abstract: One aspect of the method/apparatus finds, for each input-image pixel, an “offset weighted average” of neighboring-pixel interactions—and uses the averages to make a final image. Another aspect assumes a value for each pixel, to use in a final rendered image form—and, at each in a series of approximations, determines whether to change the value, and finds a probabilistic weight to help determine. Yet another finds, for each pixel, a numerical representation of neighboring-pixel interactions—and establishes a distance cutoff for use in defining “neighbor”, and uses the representation to decide whether to change color values. Still another finds a desired or ideal number of print passes, and adapts the number of passes actually used to the found number. Another combines halftoning and printmasking into one procedure and prints images prepared thereby. Another integrates halftoning and image filtering, to obtain esthetic visual effects, into one procedure—and prints images thus prepared.

Abstract: An imaging area includes an effective pixel section and an optical black section. Pixel signals read out from the imaging area, onto a plurality of vertical signal lines, are converted by an AD conversion circuit. The converted pixel signals are sequentially input to a signal processing circuit for computing processing. The circuit is provided with a horizontal-stripe noise suppression circuit for averaging of output signals, on a plurality of lines, which are readout from an OB section at an end in the horizontal direction in the imaging area, and for adding and subtracting of the averaged result to effective-pixel signals.

Abstract: An imaging device includes: plural pixel blocks with a predetermined number of pixel circuits of respective plural blocks set as one unit, the plural blocks being obtained by dividing a pixel area formed by arraying plural pixel circuits, which convert incident light into charges according to photoelectric conversion, in a matrix shape; and a selection control unit that selects desired ones of the pixel blocks and collectively executes reset control for discharging charges accumulated by the respective pixel circuits in the selected pixel blocks, wherein the selection control unit changes timing for executing the reset control for each of the selected pixel blocks and allocates different charge accumulating times to the pixel circuits.

Abstract: A method for compensating image data is adapted for an image sensor. The image sensor has a plurality of photo sensors arranged in an effective region and an optical black region. The method for compensating image data includes a plurality of monochromatic light representative values Si corresponding to pixel positions i is extracted from the photo sensors of the optical black region; a plurality of monochromatic image intensity values VO is extracted from the photo sensors of the effective region; the monochromatic light representative values Si are converted respectively to a plurality of monochromatic compensation values f(Si); and compensated image data VF is output after compensating the monochromatic image intensity values VO respectively based on the pixel positions i and the corresponding monochromatic compensation values f(Si). Through the method for compensating image data, a smear effect in the effective region can be compensated effectively.

Abstract: A solid-state image pickup device includes a pixel array section including an effective pixel region, an optical black pixel region, and a pixel region between the effective pixel region and the optical black pixel region; a vertical drive section which performs driving so that signals of pixels of the pixel region disposed at a side of the effective pixel region in a vertical direction are skipped and signals of pixels of the effective pixel region and the optical black pixel region are read; and a horizontal drive section which performs driving so that, from among the pixels selected by the vertical drive section, the signals of the pixels of the pixel region disposed at a side of the effective pixel region in a horizontal direction are skipped and the signals of the pixels of the effective pixel region and the optical black pixel region are read.

Abstract: A digital still camera includes an amplification circuit, a timing generator, sample hold circuits, a differential amplifier, an analog/digital conversion circuit and a control unit. The generator generates a first-pulse signal and a second-pulse signal at different timings. The circuits sample analog video signals outputted from the amplification circuit at timings when the first-pulse signal and second-pulse signal, respectively, are provided and hold levels of the analog video signals. The amplifier acquires a difference between the levels of the analog video signals. The circuit obtains a digital video signal corresponding to the analog video signal on the basis of the difference. The unit changes the timings to provide the first- and second-pulse signals to the first- and second-sample hold circuits, respectively, and a bias current depending on the driving period.

Abstract: An image display system has a capsule endoscope for capturing an in-vivo image of a subject, a receiving device for receiving the in-vivo image from the capsule endoscope, and an image display apparatus for displaying a group of in-vivo images of the subject. The capsule endoscope has an imaging unit having a black region which optical rays do not reach in an effective pixel region contributing to image capture. By the imaging unit, an in-vivo image including the signal level of the black region is detected. The receiving device receives an image signal of the in-vivo image. The image display apparatus obtains an in-vivo image group from the receiving device. The image display apparatus does not display an in-vivo image in the in-vivo image group determined as an image influenced by fluctuations in the power source voltage but displays a stable in-vivo image which is not influenced by fluctuations in the power source voltage.

Abstract: A method for processing an image abnormality caused by power supply is provided, which is used in a digital image-capturing apparatus. The method can be described as follows. First, power of the digital image-capturing apparatus is turned on. Next, a line data of an image being captured is started to be transmitted, wherein the line data has a dummy pixel region and an effective pixel region, and the dummy pixel region is first transmitted, and then a plurality of pixel data of the effective pixel region is transmitted. Next, a horizontal driving current to be input to a horizontal driver is processed, so that the horizontal driving current substantially approaches a stable state before the effective pixel region is output. Finally, the above steps are repeated for continually transmitting a next line data of the image being captured until the image of the digital image-capturing apparatus is completely transmitted.

Abstract: A data-processing circuit includes a distributor. Raw image data of horizontal 3840 pixels×vertical 2160 pixels that is periodically outputted from a CMOS-type imaging device is divided by the distributor into four blocks of partial image data. The divided four blocks of partial image data are subjected to a pre-process in parallel by first to fourth pre-processing blocks. On the other hand, raw image data of horizontal 1280 pixels×vertical 960 pixels that is periodically outputted from a CCD-type imaging device is serially subjected to a pre-process by a fifth pre-processing block. The number of pixels of the raw image data outputted from the CCD-type imaging device is equal to or less than ¼ the number of pixels of the raw image data outputted from the CMOS-type imaging device. A numerical value “4” is equivalent to the number of parallel pre-processes on the raw image data outputted from the CMOS imaging device.

Abstract: Solid-state imaging device having a plurality of vertical signal lines, includes for each vertical signal line, an effective pixel and a dummy pixel, a switch transistor provided on a path connecting the dummy pixel and the vertical signal line, and a read-out unit. The switch transistor is OFF while a first signal is outputted from the effective pixel and ON while a second signal is outputted from the dummy pixel. The read-out unit (i) reads out a level of the first signal while the switch transistor is OFF, and (ii) reads out a difference between the level of the first signal and a level of the second signal when the switch transistor is turned from OFF to ON.

Abstract: An image sensing apparatus includes a pixel array, a readout unit and an output unit having an output line group, a plurality of difference circuits, a first dummy line and a second dummy line. The output line group is interposed between the first dummy line and the second dummy line. The readout unit includes a plurality of memory circuits, each including a first holding capacitance and a second holding capacitance. A gain determined by a ratio of a capacitance value of the first holding capacitance and a capacitance value of a first output line is applied to the first signal output to the first output line, and a gain determined by a ratio of a capacitance value of the second holding capacitance and a capacitance value of a second output line is applied to the second signal output to the second output line.

Abstract: Techniques for implementing a Black Level Correction (BLC) processing operation on image data signal pixel values that results in little to no nonlinearity in the dark areas of the image due to black noise clipping, and avoids reducing image quality or adding cost, are provided. Image data signal pixel values are caused to maintain black level while being operated on by image data signal processor circuits that precede a Noise Reduction (NR) processing operation, thus allowing the BLC processing operation to be executed after the NR processing operation. With black noise mostly removed, little to no nonlinearity in the dark areas of the image due to black noise clipping results from the BLC processing operation.

Abstract: A light-sensitive pixel array has an active area and an additional area of optically shielded pixels. A “noise figure” is derived as a measure of the prevalence of noise in the image signal without being affected by the presence of moving detail in the image. The noise figure is derived by measuring the difference in output between the pixels of at least one pair of pixels in the optically shielded area in one frame, repeating this measurement in a subsequent frame, and then subtracting one pixel pair difference from the other to give a difference of differences. In a preferred form, four pairs of pixels are used. The noise figure may be used to control digital signal processing of the image signal, such as be smoothing.

Abstract: A CMOS image sensor includes: a plurality of CDS/PGAs (correlating double sampling/programmable gain amplifiers) for processing output signals of pixels corresponding to same colors on different paths; and an offset difference removing part for removing offset difference that occurs when the same color signals are processed on the different paths, wherein the offset difference removing part includes: a dummy pixel array where light is shielded; a unit for reading signals of the dummy pixel array through the CDS/PGAs and storing average offset values for each path; and a signal synthesizing unit for synthesizing the average offset values and signals of an effective pixel array, which are read through the respective CDS/PGAs, and outputting signals of which offset difference is removed.

Abstract: The present invention relates to solid-state imaging apparatus such as digital camera for outputting video signals, and more particularly relates to a solid-state imaging apparatus in which vertical stripe-like noise and horizontal shading can be corrected.

Abstract: An image-pickup apparatus configured to perform vertical-dark-shading correction with increased precision independently of photographing conditions and/or a photographing environment is provided. The image-pickup apparatus includes an image-pickup element having an effective-pixel part including plural pixel parts which are not shielded from light and a light-shielding-pixel part including plural pixel parts shielded from light, a signal-processing unit configured to set the reference level of output signals transmitted from the effective-pixel part, and a control unit configured to switch between plural areas used to set the reference level, the areas being provided in the light-shielding-pixel part, based on the photographing conditions and/or environmental conditions.

Abstract: An image sensor having an array of pixel cells, each including a photo-conversion device. The array has first, second, and third groups of pixel cells. The first group of pixel cells receives light and the second and third groups are shielded from light. Each pixel cell of the second group is configured to output a black reference signal for determining a black level of the array. Each pixel cell of the third group has at least one first transistor coupled to the photo-conversion device, and each transistor coupled to the photo-conversion device has a gate coupled to a power supply voltage.

Abstract: An imaging apparatus is provided having: a pixel unit including an effective pixel region of multiple pixels accumulating charges generated according to incident light to output signals and an ineffective pixel region of multiple pixels outputting signals not dependent on incident light; a plurality of vertical signal lines provided for each column of pixels of pixel unit; a vertical scanning circuit that scans and selects pixels of pixel unit in row units to output signals of selected pixels of same row to plurality of vertical signal lines; and a horizontal scanning circuit that scans and selects signals of plurality of vertical signal lines to output signals of selected vertical signal lines; wherein the vertical scanning circuit selects pixels of same row of effective pixel region in row units once during one frame and selects pixels of same row of ineffective pixel region in row units multiple times during one frame.

Abstract: A solid-state imaging apparatus including, among other things, a control section that, after simultaneous and concurrent reset of all first and second input sections, effects control so as to cause all the first input sections to concurrently and simultaneously accumulate the signal associated with the object image having the same exposure start timing; a correction data retaining section that retains correction data to correct a characteristic variance between the first input section and the second input section where the correction data is generated by taking a difference between a noise signal of the first input section and a noise signal of the second input section containing the characteristic variance; and a variance correction section that generates a third pixel signal corresponding to a difference between the first pixel signal and the second pixel signal where the characteristic variance is corrected by subtracting the correction data from the third pixel signal.

Abstract: A method and system for retouching digital images for a motion picture removes semi-transparent artifacts or ‘blotches’ caused by contaminates in the optical path of the camera. This approach provides the benefit of only having to retouch a single average image that is than automatically applied via a correction power map to the entire sequence of images for the affected scene. The formation of an average image tends to reinforce the artifacts making them easier to identify and reduce background detail making it easier to retouch the artifact.

Abstract: Embodiments of the invention are described that provide automated and efficient optimization of camera settings. In certain embodiments of the invention, both focus and exposure settings are determined based on an analysis of compressed images taken of a frame. Based on this analysis, the camera focus and exposure settings are set to provide a preferred image quality of the particular frame. This optimization of the focus and exposure settings is performed at each frame within the multi-frame image source. As a result, each frame image is independently optimized and addresses variations, such as light and surface inconsistencies, across the multi-frame image source.

Abstract: A defective pixel detection and correction mechanism for use in an image sensor integrated circuit determines whether a current pixel is a defective pixel in a consistent manner from frame to frame. The defective pixel detection and correction mechanism also replaces defective pixels with stable replacement values. The defective pixel detection and correction mechanism has a defective pixel detection mechanism that employs a look-up table with defective pixel locations for providing a non-varying determination of whether a pixel is defective or non-defective. The defective pixel detection and correction mechanism also has a defective pixel correction mechanism that employs a consistent replacement choice facility to provide a previous pixel value in the same frame, on the same row, and a predetermined number of pixels from the current pixel location as a replacement value and a replacement unit (e.g., multiplexer) for replacing the defective pixel value with the replacement value.

Abstract: Defect correction and other de-noising as well as resolution maintenance and contour correction can all be appropriately performed in an image-signal processing device for processing an image signal from an image sensor. First through third de-noising parts 30a through 30c are provided separately to correspond to a brightness-processing part 36, a color-processing part 40, and a contour-processing part 38, respectively. Among defect-correcting parts 42a through 42c provided to the de-noising parts 30a through 30c, respectively, the defect-correcting part 42c provided to correspond to the contour-processing part 38 is set to a low defect-correction level and maintains contour information. The defect-correcting part 42a provided to correspond to the brightness-processing part 36 is set to an intermediate correction level and corrects pixel defects while maintaining resolution.

Abstract: In a solid-state imaging device, bus lines are provided at both sides of an imaging area vertically to send vertical-transfer clock pulses to shunt wires disposed on or over the imaging area at both ends of the signal lines of the shunt wires. Bus lines disposed closer to a horizontal transfer register are placed at a boundary area of the imaging area and the horizontal transfer register. Since the bus lines pass through an upper layer of the boundary area, imaging performed by light receiving elements is not performed but dummy pixels having almost the same structure as the light receiving sections are disposed and vertical transfer registers are provided in the boundary area to just transfer signal charges by the vertical transfer registers with a characteristic similar to that in the imaging area to the horizontal transfer register.

Abstract: An image sensor having an array of pixel cells, each including a photo-conversion device. The array has first, second, and third groups of pixel cells. The first group of pixel cells receives light and the second and third groups are shielded from light. Each pixel cell of the second group is configured to output a black reference signal for determining a black level of the array. Each pixel cell of the third group has at least one first transistor coupled to the photo-conversion device, and each transistor coupled to the photo-conversion device has a gate coupled to a power supply voltage.

Abstract: According to this invention, even when an image capturing apparatus has a plurality of read modes, the frame rate can be prevented from decreasing in a high-resolution video photographing mode. The image capturing apparatus includes an image sensor and drive unit. The image sensor includes an effective image sensing area having a plurality of pixels at the center portion of the image sensor, and a light-shielded pixel area having a plurality of light-shielded pixels at the peripheral portion of the image sensor. The drive unit can drive the image sensor in a plurality of modes, and drives the image sensor such that the plurality of read modes are almost equal to the light-shielded pixel read time BL-MIN for reading pixel signals in the light-shielded pixel area.

Abstract: A method and apparatus for correcting signal differences between at least two adjacent parts of a radiation-sensitive sensor, each containing a contiguous set of radiation-sensitive sites read out through a respective separate electronic processing mean, by increasing the perimeter of the border between the adjacent parts of the sensor read out through separate electronic processing means and using at least one set of adjacent values from each of the adjacent parts to compute a correction to be applied to a signal read out of at least one of the adjacent parts.

Abstract: A solid state imaging device including: a pixel portion having a plurality of pixels arrayed two-dimensionally and including an effective pixel portion and a dummy pixel portion; a timing generator for generating address information for reading signals of pixels of the pixel portion and timing signals for reading; a column decoder; a column selection circuit for generating transfer signals and reset signals used for control for reading signals of pixels in the column portions of the pixel portion by the plurality of line selection signals output from the column decoder based on the timing signals and selecting column portions of pixels in an effective portion and a dummy portion of the pixel portion; and a transfer circuit for reading signals of corresponding pixels based on the transfer signals and reset signals output from the column selection circuit, then transferring signals of read pixels by the row signal lines.

Abstract: A solid-state imaging device includes: a plurality of light-receiving elements which are arranged by rows and columns. A driving unit performs a driving, so that a signal packet and a plurality of dummy packets in an identical column are mixed together into a mixed packet in each holding units, charges of the mixed packet are held in a hold unit, the held charges of the mixed packet are vertically transferred to a horizontal transfer unit so that the mixed packet is mixed with a mixed packet of a different hold unit which is vertically transferred from the different hold unit to the horizontal transfer unit.

Abstract: A CMOS image sensor includes a plurality of active pixel rows and an optical black pixel row. The optical black pixel row is activated to generate a respective optical black signal upon activation of each of at least two of the active pixel rows. Such sharing of the optical black pixel row reduces the optical black area of the CMOS image sensor.

Abstract: An analog front-end circuit controlling an imaging device and processing an analog image signal output from the imaging device includes: an analog processing section that receives an analog image signal from the imaging device, provides the image signal with predetermined processing, and outputs the image signal; an A/D converter that performs A/D conversion with the image signal output from the analog processing section; a transmitter circuit that receives digital image data output from the A/D converter, generates a differential signal based on the digital image data, and outputs the differential signal; and a timing generator that generates a plurality of clocks including a multiphase driving clock for driving the imaging device based on a first reference clock; the transmitter circuit including a differential amplifier circuit that generates a differential signal based on the digital image data output from the A/D converter, and outputting the differential signal generated in the differential amplifier ci

Abstract: A programmable pattern-matching device is provided that may perform bad pixel correction and image sharpening and smoothing (noise removal). Soft edges of an image are identified and adaptively sharpened. Soft edges are identified by subtracting adjacent pixel values along a diagonal, row and/or column, generating a pixel string pattern based on the pixel value differences, and comparing the pixel string pattern to predefined string patterns indicative of a soft edge. Similarly, hard edges are identified by comparing the pixel string pattern to predefined string patterns indicative of a hard edge, which are then excluded from a low pass filter applied to smooth the image in order to reduce image noise. Bad photosensors of an image sensor are detected by subtracting a pixel value for a first photosensor from its surrounding photosensors to obtain a pixel string pattern that is then compared to predefined string patterns indicative of a bad pixel.

Abstract: A signal processor formed on a single semiconductor chip having an A/D conversion unit for converting an analog signal to a digital signal, includes an operation unit for performing a calculation based on a plurality of digital signals converted by the A/D conversion unit, and a selection unit for selecting one of the digital signals converted by the A/D conversion unit and a result calculated by the operation unit and externally outputting the selection.

Abstract: In a method or system for scanning a source image, the source image is scanned with a sensor that comprises multiple line arrays designed to detect a specific color such that a color separation of the source image to be scanned is generated by each line array. The color separations represent the source image in the form of pixels. The pixels of the different separations of the source image are at least partially offset relative to one another. The pixels of the color separations are separately filtered with multiple FIR sub-filters. The filtered pixels of the source image of the multiple color separations are summed into pixels of a target image.

Abstract: The black level in raw image data captured from an image sensor does not always stay fixed at a constant level, but may change as a function of the analog gain and exposure time and may vary from one spatial location of the pixels to another. To carry out black-level correction on the raw image data, the black level of each of the color components is measured at one or more sampling locations. A look-up table is generated based on the measured black levels and a computation module is used to carry out black-level correction based on the information stored in the look-up table. The look up table may have information indicative of the analog gain level and the exposure time and the variations of black-levels in different spatial locations.

Abstract: An image sensing apparatus, having an image sensor for sensing an image of an object and an analog-digital converter which operates at a predetermined frequency and converts an analog signal read from the image sensor to a digital signal, controls the relationship between a phase of the analog signal read from the image sensor and a phase of a timing signal for operating the analog-digital converter in accordance with the peripheral condition.