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: An image sensor is provided. The image sensor includes a pixel array, an analog-to-digital converter, and a processor. The analog-to-digital converter converts a black level reference signal and a pix signal from the pixel array into a first digital signal and a second digital signal, respectively. The processor obtains a black level reference value according to the first digital signal, and obtains a compensation coefficient according to the black level reference value, a maximum digital level of the analog-to-digital converter and a full signal range value. The processor obtains pix data according to the compensation coefficient, the black level reference value and the second digital signal.

Abstract: Image capturing is performed with an image pickup element being exposed to light, whereby a plurality of pieces of exposure image data are obtained. Image processing is performed on the plurality of pieces of exposure image data. The plurality of pieces of exposure image data output are combined into combined exposure image data. A plurality of pieces of dark image data are obtained and one piece of dark reference image data is generated. Image processing that uses a parameter based on the image processing performed on each exposure image data is performed on the one piece of dark reference image data, whereby a plurality of pieces of processed dark image data are output. The plurality of pieces of processed dark image data are combined into combined dark image data. The combined exposure image data is corrected in accordance with the combined dark image data.

Abstract: An imaging device includes a solid-state imaging device configured to include a plurality of pixels, the solid-state imaging device outputting subject data according to a pixel signal output by the pixel of an image region on which subject light is incident and optical black (OB) data according to the pixel signal output by the pixel of a constantly shielded OB region of a plurality of columns or rows located on an end of the image region as image data, and an imaging processing unit configured to output pre-processed image data obtained by performing black level correction on partial subject data included in the image data using the same OB data included in the image data output by the solid-state imaging device.

Abstract: An image pickup apparatus and method which reduces fixed pattern noise appearing in multiple exposure shooting and which can obtain a high-quality multiple exposure image. Multiple pieces of exposure image data are obtained by exposing an image pickup device. The multiple pieces of exposure image data are subjected to image processing. The multiple pieces of image processed exposure image data are synthesized to generate synthesized exposure image data. Multiple pieces of dark image data are obtained by shielding the image pickup device from light. Each of the multiple pieces of dark image data is subjected to image processing equivalent to image processing performed on a corresponding one of the multiple pieces of exposure image data. The multiple pieces of image processed dark image data that are synthesized to generate synthesized dark image data. The synthesized exposure image data is corrected on the basis of the synthesized dark image data.

Abstract: Systems and methods of bad pixel cluster detection are disclosed. In a particular embodiment, a system is disclosed that includes a bad pixel correction module coupled to receive image data and adapted to perform a bad pixel cluster detection process. The bad pixel correction module includes logic to determine whether two test pixels have values that exceed a representative value of a group of surrounding pixels by more than a threshold amount. The threshold amount is determined via a table lookup.

Abstract: A black image captured in a light-shielded state is obtained, and the streak intensity is determined for each pixel of the black image from the absolute value of an AC component in a region containing the pixel. An extraction image which extracts streak-like fixed pattern noise in a captured image is generated using a black image obtained by applying, to the obtained black image, the first filter for reducing random noise in the first direction.

Abstract: A photoelectric conversion device, comprising a photoelectric conversion portion, provided in a semiconductor substrate, including a first semiconductor region of a first conductivity type, a second semiconductor region of the first conductivity type provided adjacent to the first semiconductor region, a third semiconductor region of the first conductivity type provided at a position away from the second semiconductor region, and a gate electrode provided between the second semiconductor region and the third semiconductor region, wherein the second semiconductor region is provided at a position away from the gate electrode, and the semiconductor substrate includes a region of a second conductivity type within a region extending from an edge of the second semiconductor region to below the gate electrode.

Abstract: An imaging sensor comprises a pixel array having an active imaging portion and a shielded portion. The active imaging portion provides an image signal corresponding to light incident on the pixel array. The shielded portion is shielded from the light incident on the pixel array and therefore provides a dark current signal. The imaging sensor includes a black-level adjustment circuit which adjusts the imaging signal to compensate for variations in the imaging signal black-level values. The black-level adjustment circuit includes an average value calculator to calculate an average signal value for each of a plurality of shielded regions in the shielded portion of the pixel array. A region selector is configured to select average signal values that are within a predetermined range. A black-level adjustment value calculator uses the selected values to calculate an adjustment value for the black-level of the image signal.

Abstract: According to an embodiment, an image scanning device includes: a light source unit that emits light onto an original to be scanned; a photoelectric conversion unit that converts light from the original to an electric signal; a converting unit that converts the electric signal from the photoelectric conversion unit into digital image data; and a black correcting unit that performs black correction by correcting pixel-by-pixel black levels of pixels contained in pre-scanning digital image data obtained before the original is scanned based on a ratio of a dark-current black level of a pixel contained in ongoing-scanning digital image data obtained during scanning of the original to a dark-current black level of the pixel contained in the pre-scanning digital image data, and subtracting the corrected pixel-by-pixel black levels from the ongoing-scanning digital image data.

Abstract: An image sensor may be provided that includes an image pixel array, analog column circuitry and digital column circuitry. The digital column circuitry may extract a systematic analog signal offset from data received from the analog column circuitry. The digital column circuitry may generate analog signal offset correction values based on the systematic analog signal offsets and provide the analog signal offset correction values to the analog column circuitry. The analog column circuitry may remove signal offsets from subsequently read out image data from the image pixel array using the analog signal offset correction values provided by the digital column circuitry. The image pixel array may include image pixels having color filters of various colors. The digital column circuitry may generate analog signal offset correction values corresponding to each of the various colors.

Abstract: An imaging device includes an effective pixel region outputting an effective pixel signal, a first shielded pixel region outputting a shielded pixel signal before the effective pixel signal is output, and a second shielded pixel region outputting a shielded pixel signal after the effective pixel signal has been output. In the device, in a steady state, frame clamping is performed using a clamping reference value generated from the pixel signals of the second shielded pixel region. A frame in a transition state in which the optical black signal level of the imaging device changes is subjected to frame clamping using a clamping reference value generated from the pixel signals of the first shielded pixel region.

Abstract: A solid-state imaging device includes first and second sets of pixels. The first pixels have light reception elements and a discharging unit that discharges charge corresponding to light received by the first pixels. The second pixels have corresponding light reception elements but are covered with a light shielding film. Signals stored in the second light reception elements are read to a next stage when the discharging units corresponding to the first light reception elements are enabled.

Abstract: According to embodiment, an image processing device includes a black level correcting section. The black level correcting section includes a first input restricting unit and a second input restricting unit. The second input restricting unit performs a second input restriction, having a second signal level range including a moving average as a reference, on a black level signal subjected to a first input restriction by the first input restricting unit. A correction amount calculation unit calculates a difference of an average of signal values subjected to the second input restriction and a black level standard value as a correction value to apply on an effective pixel signal.

Abstract: A black level adjustment method for a CMOS image sensor is provided. The CMOS image sensor has a pixel array with dark rows and active rows. The method has the following steps of: computing an average value of pixels from the dark rows, wherein the average value is in the form of an integer and a fraction; calculating a black level control (BLC) offset value according to the integer; generating a dithering mask based on the fraction; applying the dithering mask to pixels from the active rows; and adding the calculated BLC offset value to the dithered pixels from the active rows to generate resulting pixels.

Abstract: According to one embodiment, a solid-state imaging device includes an effective pixel portion in which effective pixels are provided, a light-shielded pixel portion in which light-shielded pixels are provided, an ADC circuit that performs an AD conversion operation for signal components read from the effective pixel and the light-shielded pixel, on the basis of a result of a comparison with a reference voltage on which a clamping voltage is superimposed, and an AD clamping circuit that calculates a clamping voltage for a target value of a black level read from the light-shielded pixel by extrapolating a relation between the clamping voltage and an AD-converted value of the black level read from the light-shielded pixel at the time when the clamping voltage is applied.

Abstract: According to one embodiment, there is provided an analog gain range determining unit that determines a range to which an analog gain setting an amplification factor of a pixel signal read from a pixel belongs, a clamp parameter control condition setting unit that sets a control condition of a clamp parameter setting the black level based on a result of the determination by the analog gain range determining unit, and a clamp parameter control unit that controls the clamp parameter based on the control condition set by the clamp parameter control condition setting unit.

Abstract: An image pickup method using an image pickup apparatus having a charge coupled device (CCD) image pickup device, the method includes: acquiring an effective pixel signal from effective pixels of a light-receiving face of the CCD image pickup device; acquiring a signal outputted from shaded pixels of the light-receiving face to calculate a representative value of the signal; controlling a variable gain amplification above a vertical period of the effective pixel signal in plus correlation with an average above the vertical period of the representative value; and controlling a variable gain amplification of a horizontal period of the effective pixel signal in minus correlation with a ratio between a value of a horizontal period of the representative value or a recursive average in screens of the representative value and an average above a vertical period of the representative value.

Abstract: Imaging systems may be provided with image sensors having verification circuitry. Verification circuitry may be configured to continuously or occasionally verify that the image sensor is functioning properly. For example, verification circuitry may be configured to monitor levels of leakage current during standby mode. Verification circuitry may be coupled between a power supply and circuitry that is powered by that power supply. When the imaging system is in standby mode, circuitry associated with the imaging system such as pixel circuitry may draw a standby leakage current. Verification circuitry may be configured to measure the amount of standby leakage current drawn by associated imaging system circuitry. If the measured level of standby leakage current exceeds a maximum acceptable level of standby leakage current, a warning signal may be generated. Standby leakage current levels on multiple power supply lines may be monitored with associated verification circuitry.

Abstract: A solid-state imaging device 1 according to an embodiment of the invention includes: pixel units P(x, y) each of which includes a photoelectric conversion element and an amplifying unit for a pixel unit and which are two-dimensionally arranged; at least one row of optical black units Pob(x, y) each of which includes a photoelectric conversion element, an amplifying unit for a pixel unit, and a light shielding film that covers the photoelectric conversion element, the photoelectric conversion element and the amplifying unit for a pixel unit being the same as those of the pixel unit P(x, y); and at least one row of optical gray units Pog(x, y) each of which includes an amplifying unit for a pixel unit which is the same as that of the pixel unit and to which a reference voltage is input. The value of the reference voltage is less than the value of the output signal from the photoelectric conversion element in a saturated state.

Abstract: An image pickup apparatus includes an image pickup unit having an optical black area, a control unit which reads a pixel from a selected area in a part of the image pickup unit, and a dark offset correction unit which sets a correction value acquisition area in the optical black area included in the selected areas. When the control unit performs a reading from a first selected area and a reading from a second selected area which at least partially overlaps with the first selected area, the dark offset correction unit sets a first correction value acquisition area set for the optical black area included in the first selected area and a second correction value acquisition area set for the optical black area included in the second selected area such that the first and second correction value acquisition areas at least partially overlap with each other.

Abstract: An apparatus, computer program product, and method for reducing persistent shadows within an image. The apparatus includes a camera configured to generate frames of the image. The apparatus also includes a computer processor. The computer processor calculates the average normalized brightness for each pixel in the image and adjusts the brightness of each pixel with the average normalized brightness.

Abstract: There is provided a denoising method of an image system that detects a brightness variation cycle of ambient light sources, records a brightness variation of at least one noise area within the brightness variation cycle and compensates the brightness variation from current images thereby removing interference from the ambient light sources. There is further provided an image system.

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 approach is provided to adjust illumination color temperature at a flash unit of a camera. Data that corresponds to the ambient light of a physical environment is collected, such as at a color temperature meter included in the camera. The ambient light has a distribution of color temperatures that cycle over a fixed time period. When a flash request is received, a time is calculated at which the flash unit will flash. One of the color temperatures is identified from the distribution of color temperatures with the identified color temperature being the predicted color of the ambient light that will be present in the physical environment when the flash unit flashes. The color temperature of the flash unit is set to the identified color temperature.

Abstract: A method for synchronizing a first circuit to an electro-optical sensor is disclosed. The method generally includes steps (A) to (D). Step (A) may generate with the first circuit a configuration signal that conveys a request to capture at least one frame of a plurality of periodic frames. Step (B) may receive the periodic frames at a second circuit from the electro-optical sensor. Step (C) may discard a first frame of the periodic frames where the first frame precedes the request. Step (D) may store a plurality of active pixels in a second frame of the periodic frames in a memory where the second frame follows the request. The second circuit is generally a hardware implementation.

Abstract: Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for performing rolling shutter distortion corrections are described. A video clip captured by a user is received and each of a plurality of predefined affine transforms for rolling shutter distortion correction is applied to the received video clip. Further, a visual indication of results from each of the plurality of the predefined affine transforms is presented to the user and input is received from the user selecting one of the visual indications. Furthermore, the predefined affine transform corresponding to the selected visual indication is associated with a device that acquired the received video clip. Additionally, the association can be stored, and the stored association can be used later to automatically perform a rolling shutter distortion correction on another video clip upon detecting that the other video clip comes from same device that already went through a calibration sequence.

Abstract: According to one embodiment, a solid-state imaging device includes a VOB region, an effective pixel region, a comparator, a holder, and a drive controller. The effective pixel region outputs the reset signal, and an image signal to the vertical signal line. The comparator compares the reset signal transferred from the VOB region through the vertical signal line with a reference signal, and determining whether the reset signal is within a digital level range. The holder is capable of holding either a value representing a first result or a value representing a second result, according to a determination result of the comparator. The drive controller varies a pulse timing period according to the value held by the holder, and automatically sets the period when the reset signal is read from the effective pixel region to the vertical signal line. A voltage of the vertical signal line is clamped in the period.

Abstract: A pedestal level compensation method includes calculating a dark level difference error depending on temperature, calculating a pedestal level offset depending on an analog gain, and compensating a pedestal level according to the dark level difference error and the pedestal level offset.

Abstract: In an image pickup apparatus, a calculation unit calculates an amount of noise and an amount of afterimage that can be included in an electric signal or image data in an image pickup operation, based on output characteristic information indicating a manner in which the amount of noise and the amount of after image change as a function of an elapsed time since a voltage is applied to a detection unit, a temperature of the detection unit detected by a temperature detection unit, the voltage supplied to the conversion elements from a power supply unit, and an image pickup operation start time indicating a time elapsed since the supplying of the voltage to the detection unit is started until the image pickup operation is started to output the electric signal corresponding to an electric charge generated by the conversion element in the detection unit.

Abstract: Provided is an imaging apparatus including an image sensor. In the image sensor that includes a valid pixel area in which a plurality of valid pixels each having a photoelectric conversion unit is disposed, a first reference pixel area in which a plurality of first reference pixels each having a light-shielded photoelectric conversion unit is disposed, and a second reference pixel area in which a plurality of second reference pixels each having no photoelectric conversion unit is disposed, when outputs of the plurality of valid pixels are added to be read, outputs of the plurality of first reference pixels are added by the addition unit to be read, and outputs of the plurality of second reference pixels are read without being added by the addition unit. Thus, noises can be effectively corrected even in the small number of invalid pixels areas.

Abstract: This invention provides an image processing method which for noise reduction and sensitization for an ordinary video camera. The noise reduction processing locates a bright pixel and averages brightness by adding the pixel accumulated by ratio in accordance with the geometric series, and to a dark pixel, carrying out the processing of noise reduction which averages brightness by adding the pixel accumulated by ratio in accordance with the geometric series and the processing of sensitization in the condition that a magnification of intensification is greater than 1, determine that the pixel moves or not, if the pixel is moving, it is used to carry out processing of sensitization only, and if the pixel is still, choose it is used to carry out the processing of sensitization and noise reduction.

Abstract: An imaging device includes a pixel array in which pixels each including a photoelectric conversion part generating and storing a signal charge in accordance with incident light are disposed in a two-dimensional matrix state, and a vertical scanning circuit performing a reset of the photoelectric conversion part by each selected row, and performing a reading of a signal of the pixel by each selected row. During a read period performing the reading, the vertical scanning circuit performs the reset for the photoelectric conversion part at an arbitrary row of which reading ends in accordance with a change of the number of rows to which the resets for the photoelectric conversion parts before exposure are performed to make the number of rows to which the resets of the photoelectric conversion parts are performed constant within the read period of each row.

Abstract: An image converter includes: a pixel array having multiple imager pixels for outputting imager pixel signals, and a readout and processing device for reading out the pixel array and for receiving and processing the imager pixel signals. The pixel array has multiple reference pixels for outputting reference pixel signals, and at least one reference current device for outputting reference currents to the reference pixels for simulating illumination intensities. The readout and processing is adapted to jointly read out, receive, and process the reference pixel signals and the imager pixel signals.

Abstract: In various embodiments, image sensors include an imaging array of optically active pixels, a dark-reference region of optically inactive pixels, and two light shields disposed over the dark-reference region and having openings therein.

Abstract: A solid-state imaging apparatus which performs a global exposure operation, in a determined imaging region, for performing exposure as matching respective start times and respective end times of all rows, comprises: plural unit pixels arranged in two-dimensional matrix and each comprising a photoelectric converting unit for generating a pixel signal by photoelectric conversion, a holding unit for holding the generated pixel signal, and a first gate for transferring the generated pixel signal to the holding unit; a first controlling line connected commonly to the first gates in the unit pixels on the same row; a vertical controlling circuit for resetting the unit pixel; and a first driving line connected to the first controlling line, and not connected to and thus independent of the vertical controlling circuit, thereby enabling to reduce a current flowing in a power supply of the vertical controlling circuit when driving electrodes of the holding units.

Abstract: A digital camera and an image sensor readout method with black level calibration are disclosed. In a readout circuit of the digital camera, a black reference for black level calibration and an analog-to-digital conversion reference voltage for analog-to-digital conversion are generated from reference voltages provided by one voltage ladder. Device-to-device variations of sensor characteristics are considered when selecting the reference voltage for generating the black reference, and, a gain between the selected reference voltage and the black reference varies with a gain of a programmable gain amplifier coupled after a compensator. The compensator subtracts the black reference from a sensed signal that the readout circuit receives from an image sensor of the digital camera.

Abstract: A solid-state imaging apparatus which performs a global exposure operation, in a determined imaging region, for performing exposure as matching respective start times and respective end times of all rows, comprises: plural unit pixels arranged in two-dimensional matrix and each comprising a photoelectric converting unit for generating a pixel signal by photoelectric conversion, a holding unit for holding the generated pixel signal, and a first gate for transferring the generated pixel signal to the holding unit; a first controlling line connected commonly to the first gates in the unit pixels on the same row; a vertical controlling circuit for resetting the unit pixel; and a first driving line connected to the first controlling line, and not connected to and thus independent of the vertical controlling circuit, thereby enabling to reduce a current flowing in a power supply of the vertical controlling circuit when driving electrodes of the holding units.

Abstract: Systems and methods are described for extending the dynamic range of imaging systems, and more particularly fluorescence or luminescence imaging systems, having low optical background and a linear detector response. Images of a sample at each of a set of exposure times are acquired, a system-level dark estimate for each exposure time is subtracted from each image to form dark-corrected images, and the different exposures (dark-corrected images) are merged into a wider dynamic-range image. Typically merging is performed on a pixel-by pixel basis.

Abstract: An imaging system may include an array of image pixels. The array of image pixels may be provided with one or more rows and columns of optically shielded dark image pixels. The dark image pixels may be used to produce verification image data that follows the same pixel-to-output data path of light-receiving pixels. The output signals from dark pixels may be continuously or intermittently compared with a set of expected output signals to verify that the imaging system is functioning properly. In some arrangements, verification image data may include a current frame number that is encoded into the dark pixels. The encoded current frame number may be compared with an expected current frame number. In other arrangements, dark pixels may be configured to have a predetermined pattern of conversion gain levels. The output signals may be compared with a “golden” image or other predetermined set of expected output signals.

Abstract: An imaging device includes a readout unit which reads out an amount of charge accumulated in a floating diffusion that accumulates a charge transmitted from a light receiving unit that photoelectrically converts incident light as a signal level; a readout control unit which controls the readout unit to perform, a plurality of times, a readout operation to read out the amount of charge of a P-phase and a D-phase accumulated in the floating diffusion; and a calculation unit which is controlled by the readout control unit and obtains differences between the signal levels which are obtained using the readout operation that is performed a plurality of times.

Abstract: A technique for obtaining a corrected pixel value is disclosed. The technique includes measuring a first dark current of a dark calibration pixel of a pixel array and measuring a second dark current of an imaging pixel of the pixel array. A dark current ratio is calculated based on the first dark current and the second dark current. An image charge is acquired with the imaging pixel where the image charge is accumulated over a first time period. A charge is acquired with the dark calibration pixel where the charge is accumulated over a second time period. The second time period is approximately equal to the first time period divided by the dark current ratio. A corrected imaging pixel value is calculated using a first readout from the imaging pixel and a second readout from the dark calibration pixel.

Abstract: A method may denoise a digital video signal produced by a photoelectric sensor as a matrix of pixel signals affected by both thermal noise and impulsive noise. The method may include estimating the noise level associated to the pixel signals, and filtering the pixel signals with an attenuation factor that is a function of the estimated noise level.

Abstract: An electronic device includes a memory configured to receive data representing light intensity values from pixels in a focal plane array and a processor that analyzes the received data to determine which light values correspond to triggered pixels, where the triggered pixels are those pixels that meet a predefined set of criteria, and determines, for each triggered pixel, a set of neighbor pixels for which light intensity values are to be stored. The electronic device also includes a buffer that temporarily stores light intensity values for at least one previously processed row of pixels, so that when a triggered pixel is identified in a current row, light intensity values for the neighbor pixels in the previously processed row and for the triggered pixel are persistently stored, as well as a data transmitter that transmits the persistently stored light intensity values for the triggered and neighbor pixels to a data receiver.

Abstract: The image qualify of an image frame from a CMOS image sensor array operated in global shutter mode may be enhanced by dispersing or randomizing the noise introduced by leakage currents from floating drains among the rows of the image frame. Further, the image quality may be improved by accounting for time dependent changes in the output of dark pixels in dark pixel rows or dark pixel columns. In addition, voltage and time dependent changes in the output of dark pixels may also be measured to provide an accurate estimate of the noise introduced to the charge held in the floating drains. Such methods may be employed individually or in combination to improve the quality of the image.

Abstract: A method for correcting column Fixed Pattern Noise (FPN) in an image sensor offers a compromise between speed and precision for calculating column FPN offsets. The present correction technique is digital, and is applied after the pixel signal voltages have been digitized by an ADC. A first Optical Black (OB) pixel is sampled and compared to a target level. An offset is stored, and an appropriate push-size is determined. Additional OB pixels are sampled and the offset is applied. The push-size is increased or decreased depending upon whether the pixel signal with the applied offset is above or below a target value. This new offset value is written to memory, and the push-size is reduced, and the process is repeated until the last OB pixel has been processed. The resulting offset is applied to the signal pixels in a column.

Abstract: Disclosed herein is an image pickup circuit including: amplifying means for amplifying a charge corresponding to an amount of light received by a photodetector, and outputting a pixel signal; ramp signal generating means for generating a ramp signal whose voltage drops with a fixed slope from a predetermined initial voltage; and comparing means for comparing the pixel signal output by the amplifying means with the ramp signal output by the ramp signal generating means. A reference potential of the pixel signal output by the amplifying means and a reference potential of the ramp signal output by the ramp signal generating means are at a same level.

Abstract: The invention relates to a device for detecting small quantities of light, comprising an electronic image converter embodied in semiconductor technology for detecting the photons representing the small quantities of light and an electronic circuit connected to the electronic image converter for reading the electronic image converter and for generating a signal representing the number of photons received by the electronic image converter, wherein the electronic image converter comprises at least 100,000 light-sensitive cells and the electronic circuit is adapted to add together the signals coming from light-sensitive cells placed on the electronic image converter.

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 target digital image is received from an image sensor. The image is contaminated by noise of unknown magnitude that is represented by a reference digital image. A process is applied that uses statistical analysis of the target digital image and of the reference digital image to estimate a magnitude of the noise for at least some pixels of the target digital image.