Abstract: An imaging apparatus includes a control unit, an imaging device, a memory, and a correction unit. The memory stores information for specifying a pixel as a defect pixel among the arrayed pixels if a variation in image data of the pixel in a period is a predetermined value or larger, the image data of each pixel being output from the imaging device when light with a constant first light-quantity level is incident on each pixel of the imaging device for the period. The correction unit obtains data for the defect pixel based on image data of a good pixel that is adjacent to the defect pixel among the arrayed pixels.

Abstract: An image processing apparatus that processes image data output from an image sensing device including a plurality of pixels, comprises: a storage unit that stores defect data at least including first information showing grades of defective pixels that are subject to correction and, with respect to each defective pixel among the plurality of pixels, address information, second information showing a grade of the defective pixel; an acquisition unit that acquires an imaging condition and an imaging environment at a time of image sensing; a determination unit that compares the first information and the second information, and determines whether defect correction of each defective pixel is necessary or not based on a comparison result; and a correction unit that performs the defect correction on image data output from a defective pixel for which the determination unit determines that defect correction is necessary.

Abstract: An image processing apparatus includes: an image obtaining unit that obtains a photographic image captured with an image sensor; a flat portion extraction unit that extracts a flat portion area within the photographic image having been obtained; and a defect information generating unit that generates defect information corresponding to the extracted flat portion area.

Abstract: An image reading apparatus includes a sheet feeding unit configured to sequentially feed a plurality of documents loaded on a document positioning plate, a reading sensor arranged in a conveyance path configured to read a document of the plurality of documents fed by the sheet feeding unit, an acquisition unit configured to acquire an interval of the document between a trailing edge of a preceding document and a leading edge of a next document conveyed through the conveyance path, and a reading unit configured to execute a first reading mode using the reading sensor to read the document conveyed at a first conveyance speed, and a second reading mode using the reading sensor to read the document conveyed at a second conveyance speed that is lower than the first conveyance speed, wherein the reading unit executes the second reading mode after the first reading mode when the interval of the document is less than a predetermined interval.

Abstract: Pixel values of focus detection pixels are suitably corrected according to reducing occurrence of a residual error of correction. A digital camera 11 includes a CCD 32, an AF detection circuit 46, a specific pixel correction unit 48 and the like. The CCD 32 has standard pixels and phase difference pixels arranged in a predetermined pattern on an imaging surface, and outputs an image signal of one frame. The AF detection circuit 46 evaluates an in-focus state by referring to a pixel value of the phase difference pixels from the image signal. The specific pixel correction unit 48 determines a first correction value by multiplying the pixel value of the phase difference pixels by a predetermined gain, and compares the first correction value with the pixel value of the standard pixels around the phase difference pixels.

Abstract: An image processing apparatus includes a location information storing section, a correction coefficient storing section, a correction object pixel location setting section, a correction object pixel data extracting section, an other-color pixel data extracting section, and a pixel data correcting section.

Abstract: An imager is provided having an image-capturing device, a display, and a view angle controller. The image-capturing device captures a subject image and outputs an image signal. The display displays a through image consisting of multiple images continuously displayed. The view angle controller controls a view angle of an image so that a ratio of an area of a subject in an area of an image is maintained at a certain value when the display displays a through image.

Abstract: An image capturing apparatus includes an image sensor 104 in which at least part of pixels arranged in two dimensions are configured as focus detection pixels with divided-pupil, a memory control circuit 113 configured to read out from a memory position information for the focus detection pixels 401, 402 stored in the memory, and a correction circuit 110 configured to identify positions of the focus detection pixels 401, 402 in the image sensor 104 based on the position information for the focus detection pixels 401, 402 and to correct a defective focus detection pixel signal using defect-free focus detection pixel signals.

Abstract: Various techniques are provided for the detection and correction of defective pixels in an image sensor. In accordance with one embodiment, a static defect table storing the locations of known static defects is provided, and the location of a current pixel is compared to the static defect table. If the location of the current pixel is found in the static defect table, the current pixel is identified as a static defect and is corrected using the value of the previous pixel of the same color. If the current pixel is not identified as a static defect, a dynamic defect detection process includes comparing pixel-to-pixel gradients between the current pixel a set of neighboring pixels against a dynamic defect threshold. If a dynamic defect is detected, a replacement value for correcting the dynamic defect may be determined by interpolating the value of two neighboring pixels on opposite sides of the current pixel in a direction exhibiting the smallest gradient.

Abstract: An array of active pixels comprises rows of pixels and row select lines for selecting rows of pixels. Each active pixel comprises a buffer amplifier for buffering an output of a photo-sensitive element. An output of the buffer amplifier can be selectively put into a high impedance state, by control of the input of the buffer amplifier, when there is a defect in the row select line for that pixel. This allows other rows, which are defect-free, to remain operating as normal. A disable line can be provided for a row of pixels and each pixel can have a switch connected to the disable line. Alternatively, a first supply line powers a row of pixels. Each pixel comprises a reset switch connected between a photo-sensitive element and the first supply line for resetting the photo-sensitive element.

Abstract: An image pickup apparatus includes an image pickup element 10 that includes unit cells capable of individually reading signals from pixels that receive light beams transmitting through different pupil positions of an image pickup lens 5, a detector 20 that generates a pair of image signals in a pupil division direction using a signal from a pixel corresponding to each of the unit cells to perform focus detection based on a phase difference, a defective pixel storage unit 22 that stores defective pixel information, and a defective pixel compensating unit 20 that compensates a signal of a defective pixel based on an output of the defective pixel storage unit. The defective pixel compensating unit 20 compensates the signal of the defective pixel using a signal obtained from a pixel disposed in a direction different from the pupil division direction with respect to the defective pixel.

Abstract: A defect pixel detection apparatus includes an image sensor which includes an effective pixel configured to have a photoelectric conversion element and an output unit configured to output a pixel signal generated by the photoelectric conversion element, a first reference pixel configured to have the same pixel configuration as the effective pixel and be optically shielded, and a second reference pixel configured to have a pixel configuration different from that of the effective pixel, a defect level acquiring unit configured to acquire a defect level of a target pixel in the image sensor, and a defect pixel determination unit configured to determine whether the target pixel is a defect pixel by comparing a defect level of the target pixel with a defect detection threshold according to a type of the pixel.

Abstract: An image sensing apparatus includes an image sensor, an optical element disposed in front of the image sensor, and a foreign substance information generation unit that generates foreign substance information for a still image from a foreign substance image obtained by sensing a foreign substance that adheres to the optical element with the image sensor, and generates foreign substance information for a moving image by performing reduction processing on the foreign substance image in accordance with the driving method of the image sensor when shooting a moving image.

Abstract: Systems and methods of bad pixel cluster detection are disclosed. In a particular embodiment, a method includes determining a correlation value corresponding to a correlation coefficient between image data and at least one bad pixel cluster pattern, and detecting a bad pixel cluster corresponding to the at least one bad pixel cluster pattern based on the correlation value exceeding a threshold.

Abstract: Whether or not a pixel output signal corresponding to a previously stored blinking defective pixel address is an abnormal value is detected. Then, when a signal value indicating a defective pixel is being output, the output signal is corrected. Deterioration of a taken image caused by excessively correcting a blinking defective pixel can be prevented from occurring.

Abstract: An imaging system comprises: an imaging unit for producing an image within a given field of view; an image defect detector for detecting a defective area from a first image that is produced by the imaging unit without a subject in the given field of view; a size enlarging unit for forming a deemed defective area having an enlarged size consisting of pixels of the first image corresponding to a defective area detected by the image defect detector and at least one of pixels adjacent to these pixels; and an image defect correcting unit for correcting a second image produced by the imaging unit with a subject located within the given view of field according to a deemed defective area formed by the size enlarging unit.

Abstract: A memory accessing apparatus and a method thereof are provided, which are suitable for methods and apparatuses that access memory data in blocks, such as a video decoder. An advanced memory mapping method is adopted to generate the column address and row address of a data word in a memory based on the logic address of the data word in a video frame. Macroblocks are organized into clusters, macroblocks of the same cluster are stored in the same row of the memory, and the orders in which the video decoder reads and writes macroblocks are rearranged so as to reduce the number of row changes in memory access and improve the throughput of memory access. Furthermore, memory accesses between the video decoder and the display controller can be coordinated.

Abstract: A camera with defective pixel compensation is provided. The camera comprises a register and a compensating unit. The compensating unit receives an image datum and a plurality of adjacent image data relating to the image datum and, according to the value installed in the register, the compensator selects a reference datum from the plurality of adjacent image data. When the image datum is greater than the reference datum by a threshold value, the compensating unit modifies the image datum according to the reference datum.

Abstract: A defective pixel detecting device determining defective pixels as correction targets in an imaging device that produces image signals is provided, and the device includes: defect information storage configured to store priority of defective pixels to be corrected; a defective pixel detector configured to detect defective pixels by comparing levels of imaging signals from the imaging device with a predetermined detection level; a priority setter configured to set priority of the detected defective pixels, based on the levels of the imaging signals of the defective pixels detected by the defective pixel detector; and a correction target determiner configured to newly determine defective pixels to be corrected based on the priority of the defective pixels out of the defective pixels that are currently detected by the defective pixel detector and the defective pixels to be corrected stored in the defect information storage, determining priority of the newly determined defective pixels to be corrected, and storin

Abstract: An image sensing apparatus includes an image sensor including a pixel array, on which a plurality of pixels are arranged, and a reading section configured to read a signal from the pixel array, a detection unit configured to detect a defective pixel in the pixel array based on a signal read from the pixel array by the reading section under a condition that the pixel array is shielded from light, and a control unit configured to control the reading section to read a signal from the pixel array under a condition that a defect tends to occur when the detection unit detects the defective pixel.

Abstract: A system and method for detecting defective pixels in a sensor. A plurality of pixel values of the sensor may be detected. The values may include those of a first pixel and each nearest neighboring pixel to the first pixel. A second pixel may have the highest value of the neighboring pixels. A third pixel may have the next highest value of the neighboring pixels. A first function may be performed on the second pixel value, producing a first output value. A second function may be performed on the third pixel value, producing a second output value. If the first pixel value is higher than the first output value, or, if the first pixel value is higher than the second output value and the second pixel value is higher than the second output value, it may be determined that the first pixel is defective.

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: A CCD image sensor has an imaging surface composed of an effective pixel area and OB areas, and first and second light receiving element groups on even-numbered and odd-numbered columns respectively in the imaging surface. These light receiving element groups have separately-controllable exposure times, and they are set to low and high sensitivities. An imaging device includes this CCD, a memory storing defective pixel information of the OB areas, an OB clamping circuit for applying an OB clamp processing to the light receiving element groups, and an image processing circuit for generating image data from the output signals of the light receiving element groups after the OB clamp processing. Referring the defective pixel information, a CPU sets one of the light receiving element groups having more OB defective pixels to low sensitivity, and the other having less OB defective pixels to high sensitivity.

Abstract: The object is to provide a uniform impression of noise for an entire image signal by performing grayscale conversion and noise reduction in a balanced manner. The signal processing unit performs first signal conversion on an image signal from an image-acquisition device and transfers the processed image signal to a correction-coefficient calculation unit. The correction-coefficient calculation unit calculates, on the basis of the image signal from the signal processing unit, an area correction coefficient for each area used for grayscale conversion of each area. A noise reducing unit uses the area correction coefficients calculated by the correction-coefficient calculation unit to perform noise reduction on the image signal from the image-acquisition device and transfers the processed signal to the signal processing unit.

Abstract: An image-capturing system diagnostic device includes: an image acquisition unit that obtains an image; and a monitoring unit that monitors a quantity of foreign matter present in an optical path by generating defect information indicating a defect at pixels caused by the foreign matter in the optical path based upon the image obtained by the image acquisition unit and calculating an areal ratio of defective pixels in the image based upon the defect information having been generated and issues a warning for a photographer if the areal ratio of the defective pixels exceeds a predetermined value.

Abstract: An opening is made in a surface intercepting a wave propagating through space. An image of an object is formed on an intermediate surface from the wave passing through this opening. After wave conversion, that is to say, after the entity of a wave is converted into a detectable wave from which a two-dimensional image can be picked up, an image is picked up with a two-dimensional image pick-up device. Distortion caused by the two-dimensional image pick-up device is corrected using a calibration grid pattern provided on the intermediate surface. The intermediate surface provides a wave converting function, distortion calibrating function, distortion-free wide field of view ensuring function, and wave entity converting function, and a place of detection elements themselves.

Abstract: An image pickup apparatus includes a photoelectric conversion element which photoelectrically converts an optical image formed by an imaging optical system to acquire image data, a read control unit which thins out pixels, as needed, and reads the image data acquired by the photoelectric conversion element, a region setting unit which sets the region of an output image, a read rule selection unit which selects the pixel thinning read rule of the read control unit, and a distortion correction unit which corrects distortion of the image data read from the photoelectric conversion element. The distortion correction unit includes a filter processing unit which executes filter processing for the image data, and a filter coefficient setting unit which sets the filter coefficient of the filter processing unit in accordance with the pixel thinning read rule.

Abstract: A method and apparatus for correcting defective pixel signals, wherein pixel signals are corrected in accordance with correction information associated with operating conditions under which an image is acquired. A method for acquiring and storing correction information in an imager device is also provided.

Abstract: A camera has a focus detection sensor that includes a plurality of first focus detection pixels and a plurality of second focus detection pixels, and that has a plurality of focus detection pixel pairs each including a first focus detection pixel and a second focus detection pixel, and stores defect information indicating a defective pixel. The camera corrects a value of the defective pixel and a value of one of the first focus detection pixel and the second focus detection pixel that forms the focus detection pixel pair with the defective pixel based on a value of a focus detection pixel of the same type that is not the defective pixel. The camera detects focusing status based on a phase difference between a first focus detection image obtained from the first focus detection pixels and a second focus detection image obtained from the second focus detection pixels after the correction.

Abstract: First pixel data of a pixel of interest is output from a first shift register, while second and third pixel data of neighboring pixels indicative of the same color are output from second and third shift registers, respectively. Differential data between estimated pixel data calculated from the second and third pixel data and the first pixel data is input to a comparator. A threshold value stored in a register is modulated by the estimated pixel data, and is input to the comparator as modulated threshold data. When the comparator judges that the differential data is greater than the modulated threshold data, a selector outputs the estimated pixel data as corrected pixel data.

Abstract: A method of pixel correction is disclosed. The method generally includes the steps of (A) calibrating a per-pixel correction model of a sensor at a plurality of different illumination levels, (B) generating a plurality of pixel values from the sensor in response to an optical signal and (C) generating a plurality of corrected values by applying the per-pixel correction model to the pixel values.

Abstract: An image capture device provided with a first memory unit, which memorizes position information of non-continuous defective pixels of a solid-state image capture component, and a second memory unit with a higher access rate than the first memory unit, which memorizes position information of continuous defective pixels. When a continuous photography mode or a video photography mode is set, defective pixel correction processing is carried out on image data corresponding to each of defective pixels according to the defective pixel position information stored at the second memory unit. Alternatively, when a still photography mode is set, image data corresponding to all defective pixels is corrected, based on both the defective pixel position information stored at the first memory unit and the defective pixel position information stored at the second memory unit. As a result, it is possible to correct defective pixels with high efficiency in accordance with conditions of photography.

Abstract: An image processing circuit includes a plurality of memories for storing line pixels of a frame constituting an image, a specific pixel detecting unit for obtaining a luminance difference value, detecting a first minimum pixel (1), detecting a second minimum pixel (1), and detecting a second minimum pixel (2) and a pixel interpolating unit for applying filter coefficients to the observation pixel and specific pixels, obtaining a total sum of results of applying each filter coefficient to each pixel, and dividing the total sum by a total sum of filter coefficients of N×N pixels to obtain an interpolated value for the observation pixel.

Abstract: Methods for detecting defective pixels in imaging arrays involve establishing probabilities that individual pixels are defective and updating those probabilities by analysing images acquired by the imaging arrays. Probabilities may be evaluated for each of two or more defect conditions. The methods may be used to detect defects such as stuck-low, stuck-high, high-sensitivity, low sensitivity, hot, and defect-free conditions. Other more complicated defect conditions can also be detected. Apparatus for detecting defective pixels may be integrated with a camera or other imaging device or provided separately.

Abstract: A method, apparatus and system that allows for the identification of defective pixels, for example, defective pixel clusters, in an imager device. The method, apparatus and system determine, during use of the imager device, that a pixel defect, e.g., cluster defect, exists and accurately maps the location of the defective pixel. By analyzing more than one frame of an image, the method increases the accuracy of the defect mapping, which is used to improve the quality of the resulting image data.

Abstract: A method for correcting a pixel defect of a solid-state image pickup device includes acquiring deviation of image signals obtained by imaging respective spectral lights at specific image pickup position or at vicinities of the specific image pickup position by image pickup device; comparing the deviation with a reference value; detecting a pixel defect in an image pickup device which has imaged one of the spectral lights based on the comparing result; and correcting a pixel defect. For each detected pixel defect, at least address in an image frame, deviation, and information specifying one of the spectral lights are stored, and a determination on a pixel defect correction is made based on the above information.

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: A method for detecting defects in camera modules is provided. The method includes the following: an image is acquired from the camera module; a comparison formula and a standard value of defect luminance are set; the image is divided into many test regions; the corresponding reference regions are then plotted out; a test region is selected, and a reference region is confirmed correspondingly; averages of gray scale values of the selected test region and the confirmed reference region are calculated; a defect luminance of the selected test region is calculated; the calculated defect luminance is compared with the standard value for confirming whether the camera module is of satisfactory quality. A related system is also disclosed.

Abstract: An image sensor may have a pixel array and an imaging lens for forming an image on the pixel array. The sensor may also include a pixel readout unit for enabling individual pixel values to be readout. The sensor may further include a pixel selection unit wherein at least one pixel sub-array is selected according to the pixel values readout and the at least one sub-array is used for reading the image.

Abstract: A method and apparatus that allows for the correction of multiple defective pixels in an imager device. In one exemplary embodiment, the method includes the steps of selecting a correction kernel for a defective pixel, determining average and difference values for pixel pairs in the correction kernel, and substituting an average value from a pixel pair for the value of the defective pixel.

Abstract: An image processing apparatus comprises: a storage unit storing a first group of defective pixel data including positional information on a defective pixel of an image sensor and information on a type of defect; a detection unit which detects a defective pixel of the image sensor and generates a second group of defective pixel data; a combining unit which combines the first and second groups to generate a third group; and a correction unit which corrects an image signal output from a defective pixel of the image sensor using the third group, wherein the combining unit assigns a priority level corresponding to the type of defect to each piece of defective pixel data, and if there are multiple pieces of defective pixel data including common positional information, leaves the defective pixel data in the order of priority level, the highest the first and the lowest the last.

Abstract: An edge directed demosaicing algorithm for determining an edge direction from an input color filter array (CFA) sampled image is disclosed. Aspects of the present invention include calculating for a current missing green pixel, interpolation errors in an East-West (EW) direction at known neighboring green pixels, and averaging the EW interpolation errors to obtain an EW error. Interpolation errors are also calculated for the current missing green pixel in a North-South (NS) direction at known neighboring green pixels, and the NS interpolation errors are averaged to obtain a NS error. An EW or NS direction indicated by a minimum of the EW error and the NS error is then selected as the edge direction.

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: An apparatus and method for identifying aberrant pixels in an image sensor. The apparatus includes a light sensitive element configured to detect a first signal value representing a first level of an incident light and a light sensitive region separate from the light sensitive element configured to detect a second signal value representing a second level of the incident light. Comparing circuitry is configured to compare the first signal value and the second signal value and to output a signal indicating the pixel is an aberrant pixel if the first and second signal values differ by more than a maximum threshold value or less than a minimum threshold value in a threshold value range.

Abstract: A focus detecting device includes a focus detecting optical system which forms a plurality of object images. A photoelectric conversion element array includes a plurality of pixels and subjects each of the plural object images formed by the focus detecting optical system to photoelectric conversion. An electric charge transfer path transfers an electric charge obtained by the photoelectric conversion subjected by the photoelectric conversion element array. A focus detecting section performs focus detection with respect to a plurality of focus areas on the basis of a signal associated with an electric charge transferred by the electric charge transfer path. A plurality of effective pixel regions corresponding to the plural focus areas are arranged in the arrangement direction of the pixels of the photoelectric conversion element array, and ineffective pixel regions are arranged between the plural effective pixel regions.

Abstract: A solid-state imaging device includes: a pixel array unit formed by two-dimensionally disposing a plurality of pixels each having a photoelectric conversion portion; one or more SRAMs; a memory control section controlling writing of pixel data sequentially output from the pixel array unit into the SRAM and controlling readout of the pixel data from the SRAM; a correction process section performing a process of correcting the pixel data read from the SRAM by the memory control section; a defect detecting section detecting a defective address in the SRAM; and a defect relieving section holding pixel data to be written in the defective address of the SRAM by the memory control section and outputting the pixel data held therein to the correction process section instead of the pixel data which has been written in the defective address of the SRAM.

Abstract: A method, apparatus and system that allows for the identification of defective pixels, for example, defective pixel clusters, in an imager device. The method, apparatus and system determine, during use of the imager device, that a pixel defect, e.g., cluster defect, exists and accurately maps the location of the defective pixel. By analyzing more than one frame of an image, the method increases the accuracy of the defect mapping, which is used to improve the quality of the resulting image data.

Abstract: A system that automatically adjusts a threshold value of cross color suppression and a method thereof are disclosed. The system includes a cross color suppression unit, a statistical unit and an adjustment unit. The cross color suppression unit is for receiving input video data and searching a plurality of cross color dots thereof. According to a threshold value, the cross color suppression unit determines whether the cross color dot is static or dynamic, suppresses the static cross color dot and then generates an output video data. The method used by the present invention is, the statistical unit calculates residual cross color amount of the output video data that has been suppressed. Then, the adjustment unit compares the cross color amount of the output video data with a reference value so as to send a corresponding adjustment signal to the cross color suppression unit to adjust the threshold value.

Abstract: Various techniques are provided for the detection and correction of defective pixels in an image sensor. In accordance with one embodiment, a static defect table storing the locations of known static defects is provided, and the location of a current pixel is compared to the static defect table. If the location of the current pixel is found in the static defect table, the current pixel is identified as a static defect and is corrected using the value of the previous pixel of the same color. If the current pixel is not identified as a static defect, a dynamic defect detection process includes comparing pixel-to-pixel gradients between the current pixel a set of neighboring pixels against a dynamic defect threshold. If a dynamic defect is detected, a replacement value for correcting the dynamic defect may be determined by interpolating the value of two neighboring pixels on opposite sides of the current pixel in a direction exhibiting the smallest gradient.

Abstract: There is a provided an image processing device having: a storage section for storing defective pixel information expressing defective pixels of an image pickup element; a correction section that, on the basis of the defective pixel information, carries out correction of defective pixels on an image captured by the image pickup element; a point defect detector that, on the basis of a first image for defect detection which has not been subjected to defective pixel correction, detects point defects of the image pickup element in accordance with point defect detecting conditions; a line defect detector that, on the basis of a second image for defect detection which has not been subjected to defective pixel correction, detects line defects of the image pickup element in accordance with line defect detecting conditions; and a defective pixel information register storing the results of detection.