Abstract: A digital image acquisition device is for acquiring digital images including one or more preview images. A face detector analyzes the one or more preview images to ascertain information relating to candidate face regions therein. A speed-optimized filter produces a first set of candidate red-eye regions based on the candidate face region information provided by the face detector.

Abstract: A photographing apparatus includes: a photographing unit having an image pickup device, the photographing unit carrying out first photographing for obtaining a first image with the image pickup device being set in an exposure state, and second photographing for obtaining a second image with the image pickup device being set in a light-shielded state; a correcting unit for correcting the first image based on the second image to obtain a corrected image; and a photographing controlling unit for controlling priorities between new first photographing and the second photographing if an instruction for carrying out the new first photographing is given during the second photographing.

Abstract: A noise reducing device captures image data obtained by capturing a field with an image capturing part and a plurality of blackout image data obtained by capturing the field with the image capturing part under a light shielded state. This device reduces non-correlative random noise in the plural blackout image data. With random noise reduced, fixed pattern noise appears more accurately in resultant as blackout image data B. This device reduces the fixed pattern noise in the image data by using this blackout image data B.

Abstract: An imaging apparatus includes an image sensor that comprises a pixel portion having a plurality of pixel sensors configured to generate an image signal, and a plurality of temperature sensors disposed in an area of the pixel portion and configured to generate a temperature signal corresponding to a detected temperature, and a correction unit configured to correct the image signal from the plurality of image sensors according to the temperature detected by the plurality of temperature sensors.

Abstract: A solid-state image sensor includes a pixel array unit including a plurality of pixels arranged in the form of an array, column signal lines adapted to transmit pixel signals output from pixels in respective columns, a noise adding unit adapted to add temporally constant and two-dimensional spatially random noise to the pixel signals transmitted via the column signal lines, and an analog-to-digital converter adapted to convert a signal level and a reference level of each pixel signal including the noise added thereto by the noise adding unit.

Abstract: An imaging apparatus is provided for reducing noise which is derived from random noise contained in a correction signal used for correcting an image data and is newly generated on correction of the image data. The imaging apparatus drives vertical transfer registers with no signal charge from photoelectric transducers read out to the vertical transfer registers to obtain and store a correction signal into a field memory. The apparatus subtracts the correction signal from the image data by a subtractor.

Abstract: An image sensing apparatus comprises an image sensor configured to convert an optical image of a subject into image signals by photoelectric conversion. The image sensing apparatus acquires information for estimating a magnitude of a dark current in the image sensor, and, on the basis of the acquired information, selects any one of vertical linear noise correction processing, black subtraction processing, and normal readout processing in which neither the vertical linear noise correction processing or the black subtraction processing is carried out. Then, the image sensing apparatus carries out the vertical linear noise correction processing to correct a vertical linear noise in an image if the vertical linear noise correction processing is selected, or the black subtraction processing to correct a vertical linear noise and a fixed pattern noise in an image if the black subtraction processing is selected.

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 image sensing apparatus includes an image sensing unit that performs image sensing by converting incoming light into electrical signals, a control unit that controls driving of the image sensing unit so as to read out the electrical signals by each area of a plurality of areas of the image sensing unit, and a signal processing unit that processes the electrical signals read out by each of the plurality of areas. The control unit varies a horizontal cycle that drives the image sensing unit for each of the plurality of areas.

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: A method is for processing a Bayer domain signal of an image sensor to model an integrated noise in the image sensor. The method includes receiving the Bayer domain signal of the image signal, setting a plurality of noise models using the Bayer domain signal, and determining an integrated noise level in the image sensor based on the plurality of noise models. The noise models include a dark-current noise model, a shot noise model and a fixed-pattern noise model.

Abstract: An image sensor including a first pixel positioned between second and third pixels, each of the first, second and third pixels comprising a photodiode region surrounded by an isolation trench; a first charge transfer gate comprising a first column electrode surrounded by an insulating layer and positioned in an opening of the isolation trench between the first and second pixels, the first column electrode being configured to receive a first transfer voltage signal; and a second charge transfer gate including a second column electrode surrounded by an insulating layer and positioned in an opening of the isolation trench between the first and third pixels, the second column electrode being configured to receive a second transfer voltage signal.

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: Methods and apparatuses for row-wise dark level non-uniformity compensation of imaging sensor pixel signals. A column dependent dark reference value is determined as one of a linear and parabolic function of signal values from two areas of dark reference pixels and a column location and then used for dark level non-uniformity compensation of signal values from imaging pixels.

Abstract: A noise eliminator is provided which can highly compress and store dark current noise components while maintaining characteristics, including many high frequency components. A noise distribution analysis section 10 determines the magnitude distribution of dark current noise components of at least some pixels, and then computes the threshold and typical values for quantization based on this distribution. A quantization section 12 quantizes the dark current noise components based on the computed threshold value, and a memory 14 stores the quantized dark current noise components. An inverse quantization section 16 inversely quantizes the quantized dark current noise components stored in the memory 14 with reference to the typical value computed by the noise distribution analysis section 10. The inversely quantized dark current noise components are supplied to a subtraction section 18, and the subtraction section 18 subtracts the inversely quantized dark current noise components from an image signal.

Abstract: The challenge of the present invention is to suppress a variation in brightness of an image and make a reference value of a black level converge at an appropriate value in a short time. A condition judgment circuit judges whether or not a frame of an amount of change in gains of a variable gain amplifier being equal to or greater than a threshold continues for a predefined frames or more. If a frame of an amount of change in the gains being equal to or greater than the threshold continues for the predefined frames, a black level value of the current frame is set for new black level reference. If not continues for the predetermined number, the previous black level reference value is retained in lieu of correcting the black level.

Abstract: According to one embodiment, a black level adjusting apparatus includes a black-level correcting unit that generates a clamp parameter based on an OB value (a pixel signal value) obtained by A/D-converting, with an A/D conversion circuit, an imaging signal of an optical black section of a solid-state imaging device and feeds back clamp voltage corresponding to the clamp parameter to the A/D conversion circuit. The black-level correcting unit updates the clamp parameter using a linear relation between the clamp parameter and the OB value.

Abstract: An object of the present invention is to provide an image processing apparatus that obtains a high-quality image signal by determining an amount of noise in an optimum fashion and reducing the amount of noise. The image processing apparatus reduces a noise component contained in the image signal picked up by an image pickup element and digitized. The image processing apparatus includes a determining unit which determines whether or not a target pixel in the image signal is within a predetermined noise range for each pixel, and a noise reducing unit which reduces the noise of the target pixel based on the determination result.

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: Provided is a 4-transistor CMOS image in which a driving condition or a pixel structure is changed so that a transfer transistor in a pixel operates in a pinch-off condition during reset and transfer operations in order to reduce dark current and fixed-pattern noise caused by a change in an operation condition of the transfer transistor and inter-pixel characteristic discrepancy. The image sensor includes a photosensitive pixel including a transfer transistor for transferring photon-induced charges created in a photodiode; and a voltage control unit for controlling a turn-on voltage applied to a gate of the transfer transistor to be lower than a floating diffusion node voltage plus the threshold voltage of the transfer transistor during a partial or entire section of a turn-on section of the transfer transistor such that the transfer transistor operates in a pseudo pinch-off mode.

Abstract: An image sensor includes an array of pixels used in capturing images. First dark floor values are captured at a first time from substantially all of the pixels in the array. Contemporary dark floor values are captured at a second time from substantially all of the pixels in the array, where the second time is subsequent to the first time. The first and contemporary dark floor values are then used to compute adjusted dark floor values. The adjusted dark floor values are used when processing one or more the captured images.

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 signal chain of an imaging system is disclosed. The system includes three circuit stages. The first circuit stage includes a programmable gain amplifier (PGA) and a black level compensation (BLC) circuit that form a BLC loop. The second circuit stage includes an analog-to-digital converter (ADC), where a dark signal offset is added at an input of the ADC. The third circuit stage includes a digital gain circuit and a digital loop that makes a final output of the imaging system settle on a target level in the BLC mode.

Abstract: A defective pixel specifying method and a defective pixel specifying system for a semiconductor device having a defective pixel are provided. Also provided are an image correcting method and an image correcting system for making a defective pixel inconspicuous on the screen when a read image is displayed. The present invention determines whether or not there is a defective pixel for each pixel and specifies the coordinate of the defective pixel using image signals obtained by reading a plurality of images. The image signal of the defective pixel is set based on the image signals of the pixels adjacent to the defective pixel to correct the image of the subject read.

Abstract: A method and apparatus for reducing temporal row noise by sampling pixel signals and a separate signal representing noise. The pixel signals and noise signals are used in a correlated differential sampling operation.

Abstract: A system and method for canceling dark photocurrent in a color sensor circuit is disclosed. A color sensor is described including a color sensor circuit, a dark color sensor circuit, and a differential amplifier circuit. The color sensor circuit receives photocurrent from a color component of a light input. The color sensor circuit outputs a first voltage indicating intensity of the color component. The dark color sensor circuit receives dark photocurrent and outputs a second voltage indicating an offset voltage. The differential amplifier circuit is coupled to the color sensor circuit and to the dark color sensor circuit. The differential amplifier circuit receives the first and second voltages and outputs a final output that cancels contributions of the offset voltage in the first voltage due to the dark photocurrent.

Abstract: A method for reducing dark current within a charge-coupled device, the method includes each gate phase n having a capacitance Cn, voltage change on the gate phase n given by ?Vn such ? n ? C n ? ? ? ? V n ? 0 ; for the first time period, maintaining a set of first gate phases holding charge in the accumulated state and maintaining a set of second gate phases not holding charge in the depleted state; for a second time period, clocking the charge into a set of third gate phases in the depleted state and clocking the second set of gate phases not holding charge into the accumulated state; for a third time period, clocking the third set of gate phases holding the charge into the accumulated state and clocking a fourth set of gates not holding the charge into the depletion state; wherein the second time period is shorter than the first and third time periods.

Abstract: A sensor including an array of sensor elements generates an image responsive to electromagnetic radiation exposure. The sensor reads coordinates for predetermined hot sensor elements and calculates a dark count for each hot sensor element. The sensor determines a temperature indicator based on the dark count for the hot sensor elements and calculates the dark count for all sensor elements based on the temperature indicator. Based on the dark count the sensor is able to compensate for dark current.

Abstract: A solid-state image pickup apparatus selects, in a first image pickup circumstance in which dark current is liable to occur in vertical transfer paths of an array of photo-sensors, a first transfer mode in which the potential well capacity in the vertical transfer paths is relatively small, and, in a second image pickup circumstance in which the dark current is small in quantity, a second transfer mode which is greater in potential well capacity than the first transfer mode. As a positive voltage applied to the read-out gates of the photo-sensors, a first voltage mode indicating a relatively low positive voltage that suppresses impact ionization is set in the first image pickup circumstance, and, a second voltage mode indicating a positive voltage higher than in the first voltage mode is set in the second image pickup circumstance so as to cause the impact ionization.

Abstract: A digital still camera has a CCD image sensor, which includes an active pixel area for image pickup of an image to produce image data. A black pixel area is disposed outside the active pixel area, and produces black pixel data. The image pickup apparatus includes an amplifier for adjusting white balance of the image data. A smear detection unit detects a smeared portion of a smear phenomenon in the image according to the black pixel data. A tone correction unit reduces chroma of the image in a predetermined hue area according to a smear level of the smear phenomenon determined from the black pixel data, to carry out color correction of the smeared portion for the image data after adjusting the white balance.

Abstract: A solid-state image pick-up device is configured for more effectively reducing dark current of an interlace scanning type of CCD so that electrodes connected to transfer shift gates are sequentially arranged on two adjacent vertical transfer paths and are driven such that signal charges are prevented from staying longer in the vertical transfer path below the electrodes connected to the transfer shift gates. This prevents signal charges from waiting longer for vertical transfer during a horizontal transfer period, thereby reducing dark current otherwise caused in the vertical transfer paths.

Abstract: An image-signal processing apparatus (1) designed to process the signals output from a CCD image sensor (10) that reads pixel data for one screen, line by line, divides the pixel data into a plurality of channels and outputs the pixel data thus divided. The image-signal processing apparatus (1) detects and corrects the black level of each pixel data item that the image sensor (10) has output for one channel. The image-signal processing apparatus (1) detects and corrects the gain difference between channels, which pertain to the pixel data items output from the image sensor (10). Hence, the apparatus (1) can correct the black level of each pixel data item and the gain difference between channels with high accuracy, when used in combination with an image sensor that divides pixel data into a plurality of channels.

Abstract: An electronic camera includes an imager. An imager outputs an image signal that is based on electric charges produced on an imaging surface having an optical black area. A clamper clamps the image signal outputted from the imager by referring to a signal level of the optical black area. A processor processes the image signal outputted from the clamper by referring to a parameter setting. A restrictor restricts behavior of the clamper corresponding to a specific area allocated to the optical black area. An adjustor adjusts the parameter setting based on an output of the clamper corresponding to the restricting process of the restrictor.

Abstract: An image pickup apparatus that make it possible to perform image processing under appropriate conditions and secure appropriate image qualities of taken images. The image pickup device has a photoelectric conversion element portion that generates signal electric charge according to the amount of received light, a first optical black unit having a light-shielded photoelectric conversion element structure and having first output characteristics, and a second optical black unit having a light-shielded photoelectric conversion element structure and having second output characteristics different from the first output characteristics. A dark current value is measured based on an output from the first optical black unit and an output from the second optical black unit. Whether or not to perform image processing is determined according to the measured dark current value.

Abstract: An image capturing apparatus includes an image sensor including a first reference pixel for black level, a second reference pixel for black level, and an effective pixel, and a processing unit which applies first processing to an output signal from the effective pixel based on an output signal from the first reference pixel for black level, and applies second processing to an output signal from the effective pixel based on an output signal from the second reference pixel for black level. The first reference pixel for black level and the second reference pixel for black level each include a charge-voltage converter which converts electric charge into a voltage and a pixel amplifier which amplifies the voltage of the charge-voltage converter. The pixel amplifiers of the first reference pixel for black level and the second reference pixel for black level differ in arrangement.

Abstract: A solid-state imaging apparatus includes: a pixel section where a plurality of pixels for effecting photoelectric conversion are two-dimensionally arranged, having an effective pixel section consisting of pixels for receiving object light and a reference pixel section consisting of pixels shielded from light; a first scanning circuit for sequentially setting to the pixel section the pixels to be read out a signal; a noise suppressing circuit for suppressing noise components of signals from the pixels based on a first control signal associated with sampling and holding of signals from the pixels and a second control signal associated with setting of clamping potential that are applied at respective predetermined timings; a second scanning circuit for sequentially reading signals of each pixel suppressed of the noise components; and a reference signal control section for applying the first and second control signals to the noise suppressing circuit so that it is brought into one or the other of a first conditio

Abstract: A method for checking the functional reliability of an image sensor evaluates statistical fluctuations in the grey-scale values provided by the pixels of the image sensor. An actual noise factor, which is derived for light impinging on the pixels, is evaluated. A pixel failure is assumed if the actual noise factor misses a predetermined criterion defined by a reference noise factor. According to one embodiment, the reference noise factor is a dark noise factor. An electronic camera that operates in accordance with the above-described method is also disclosed.

Abstract: Methods, devices, and systems for offset compensation in an amplifier are disclosed, wherein the amplifier inputs may be exposed to large loads from an array of pixel columns coupled in parallel. During a sampling phase, an amplifier offset may be sampled by selectively coupling a first amplifier output to a first amplifier input and a second amplifier output to a second amplifier input. During a portion of the sampling phase, the first amplifier output may be buffered to a first storage element. During a different portion of the sampling phase, the second amplifier output may be buffered to a second storage element. To sense the pixel columns during an amplification phase, the first storage element and the second storage element are coupled to the first and second amplifier inputs, respectively, with the result that the amplifier offset is canceled from the amplifier output.

Abstract: An image correction apparatus includes a dark-pixel-region extracting unit that extracts a dark pixel region of image data photographed by a photographing unit, a dark-pixel-area calculating unit that calculates an area of the dark pixel region extracted by the dark-pixel-region extracting unit, a luminance-value-variance calculating unit that calculates variance of luminance values of pixels in the dark pixel region extracted by the dark-pixel-region extracting unit, and an image correction unit that corrects brightness of the image data in accordance with the area calculated by the dark-pixel-area calculating unit and in accordance with the variance of the luminance values calculated by the luminance-value-variance calculating unit.

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 image pick-up device includes a first correlated double sampling circuit configured to generate a first sampling signal by performing correlated double sampling on an active pixel signal output from an active pixel and generating a first comparison signal by comparing the first sampling signal with a reference signal, and a second correlated double sampling circuit to generate a second sampling signal by performing correlated double sampling on an OB pixel signal output from an optical black pixel and generating a second comparison signal by comparing the second sampling signal with the reference signal.

Abstract: In a solid-state image pickup device, it is difficult to match an optimum incidence angle corresponding to an image height of a pixel array region with light incidence characteristics of a camera lens, thereby causing image quality deterioration due to sensitivity shading. Respective microlenses are disposed in a two-dimensional manner, i.e., in a row and a column directions. In particular, the microlenses are disposed such that each side of a disposition region where the microlenses are disposed has a concave curve with respect to a line connecting adjacent vertexes of the disposition region. In other words, a distance AH (AV) between center points of a pair of facing sides of the disposition region is set to be smaller than a distance BH (BV) between neighboring vertexes of the disposition region.

Abstract: A noise reducing device captures image data obtained by capturing a field with an image capturing part and a plurality of blackout image data obtained by capturing the field with the image capturing part under a light shielded state. This device reduces non-correlative random noise in the plural blackout image data. With random noise reduced, fixed pattern noise appears more accurately in resultant as blackout image data B. This device reduces the fixed pattern noise in the image data by using this blackout image data B.

Abstract: An imager having optically and electrically black reference pixels in each row of the imager's pixel array. Since the reference pixels of each row experience the same row-wise noise as active imaging pixels in the associated row, the signals from the reference pixels are used to cancel out row-wise noise from the row of imaging pixels. The reference pixels are designed such that their photosensors are physically or effectively removed from the row-wise noise correction, thus rendering them electrically black or dark. As such, the reference pixels can be used to provide row-wise noise correction without the adverse effects of warm and hot pixels.

Abstract: A digital camera captures high quality long exposure images by capturing and summing several images of the same scene. The effective ISO of the camera is reduced by scaling the summed image, thus reducing image noise and improving long exposure quality.

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: An image reading apparatus is provided which includes a contact image sensor comprised of a plurality of sensor chips arranged in series, an analog image processor for processing an analog image signal from the contact image sensor, a unit for conducting black shading correction for each pixel and a unit for conducting white shading correction for each pixel. The image reading apparatus further includes a unit for digitally monitoring a black offset value corresponding to each chip with respect to the signal that has been processed by the analog image processor and a unit for adding and subtracting a black offset variation amount for each chip in the previous stage of the unit for conducting black shading correction for each pixel, and corrects black offset based on an instruction of a control unit.

Abstract: An improved on chip test method for determining the photon transfer curve (PTC) and dark current in an image sensor is described. Cost and time savings is achieved by reducing the number of frames necessary for the measurements to three including two exposure frames and one frame for dark current testing. A conventional test involving “n” different exposure times each with two frames is replaced by implementing a snap shot mode where a first plurality of pixel rows are exposed for a time t1, a second plurality of pixel rows are exposed for a time t2, and so forth up to an nth plurality of pixel rows exposed for a time tn where the total number of pixel rows equals a frame and tn>t2>t1. The resulting image has “n” regions each with a different brightness that become progressively brighter from top to bottom of the image.

Abstract: A method is disclosed as including scanning a first pixel of an image with a primary scanning line of a sensor, and scanning a second pixel of the image with a secondary scanning line of the sensor, wherein the first pixel is separated from the second pixel by a pitch of one or more scan lines. A compensation value is determined for one or more pixels of the image, wherein the compensation value is determined based, at least in part, on a mathematical operation comprising pixel values associated with the first and second pixels and the pitch. The method further includes compensating the one or more pixel values based, at least in part, on the compensation value, wherein the compensation value compensates for a reflection of light between the first and second scanning lines when the first and second pixels are scanned.