Abstract: Provided are a digital photographing apparatus, and associated method and recording medium with method instructions, by which smear generation during moving picture photographing or moving picture display is effectively reduced. The digital photographing apparatus includes an imaging device having an effective area that generates first image data from incident light and an optical black area that is disposed outside the effective area and extends horizontally; a first smear correction unit that corrects the first image data generated by the effective area by using smear data generated by the optical black area, thereby acquiring second image data corresponding to a second frame image comprising less smear than a first frame image corresponding to the first image data; a unit corrects the second image data thereby acquiring third image data.

Abstract: An imaging apparatus includes a pixel unit array and a driving unit. Each pixel unit includes a plurality of photoelectric conversion units, a charge-voltage converter common to the plurality of photoelectric conversion units, a plurality of transfer units which transfer electric charges generated by the plurality of photoelectric conversion units to the charge-voltage converter, an output unit which outputs a signal based on the electric charges to a signal line, and a setting unit which sets the electric potential of the charge-voltage converter. Each pixel unit is selected or deselected in accordance with the electric potential set in the charge-voltage converter. The driving unit drives the pixel unit array so that the output unit continuously outputs, to the signal line, the signal based on the electric charges generated by the plurality of photoelectric conversion units in the selected pixel unit without performing an operation of deselecting the selected pixel unit.

Abstract: An imaging apparatus includes an image pickup device that images a photogenic subject, a drive part that drives the image pickup device in order to read out image signals from the image pickup device, a digital signal processing part in which image signals outputted from the image pickup device are inputted and processed, one image display part connected to the digital signal processing part and configured to display using one display format a processed image, another image display part connected to the digital signal processing part and configured to display using another display format the processed image and which requires more time for display processing than the time required for display processing by the one display format and an image switch-over part for switching over an image display device between the one image display part and the another image display part.

Abstract: When the quantity of light diagonally entering light-receiving portions of an image-capturing element in an electronic camera is large and thus an electrical charge is generated readily in an electrical charge transfer line, hue correction processing is executed to correct any change occurring in the hue induced by the charge generated in the electrical charge transfer line.

Abstract: Image data of a digital signal is inputted to a digital signal processor. A CPU reads out color correction coefficients from a ROM. Weights are added to the color correction coefficients based on information regarding transfer efficiency of a CCD image sensor such that the coefficients in a horizontal direction are set larger than those in a vertical direction. Further, an interpolation processor calculates horizontal and vertical components of R, G, and B colors of each pixel through color interpolation processing based on image data of each pixel and its peripheral pixels. A linear matrix circuit is controlled by the CPU and subjects the horizontal and vertical components to linear matrix operation using the color correction coefficients, thus subjecting each pixel data to color correction processing.

Abstract: An image processing apparatus includes a blur reproducing unit that generates blur-reproduced image data by reproducing a predetermined blur of a lens, with respect to blur-corrected image data of which an initial data is input image data inputted from an image sensor; a blur correcting unit that corrects the blur-corrected image data so that an error between the blur-reproduced image data and the input image data becomes smaller; and a curved-surface fitting unit that obtains curve surface parameters of each functions approximating distribution of pixel values of each of color components of the blur-corrected image data so that curved-surface shapes of the functions become the same among the color components, and updates the pixel values of the blur-corrected image data by using the curve surface parameters.

Abstract: Provided is a solid-state imaging device including a plurality of vertical transfer units (VCCDs), a horizontal transfer unit (HCCD) and a driving unit.

Abstract: A method for correcting for hue artifacts captured by an imager associated with a color filter array including first, second and third color pixels and optical system spaced from the imager, wherein a first group of second pixels are primarily influenced by adjacent first pixels and a second group of second pixels are primarily influenced by adjacent third pixels, includes separately blurring or smoothing the first and third pixels and the first and second group of second pixels; based on the difference between adjacent pixels of the first and second group of second pixels, correcting for hue in the second group of second pixels; and correcting for adjacent third pixels based on the correction for adjacent second group second pixels.

Abstract: Each unit pixel includes a photodiode, a reading selection transistor, a reading transistor, an amplifying transistor, a reset transistor, and a horizontal selection transistor, and thus a MOS image sensor of a dot-sequential reading 5-Tr type is formed. The reading selection transistor and the reading transistor are formed with a two-layer gate structure, and gate potential of the reading selection transistor and the reading transistor is set to a negative potential. Thereby, a lower layer of a gate region of the reading transistor and the reading selection transistor is controlled to a negative potential. Thus, depletion in the lower layer region is suppressed to reduce leakage current.

Abstract: An auto-focusing method and a digital image processing apparatus using the same are disclosed. The auto-focusing method includes: setting a reference noise level if an illuminance of a photographing area is larger than a predetermined reference value, and setting a variable noise level that varies according to the illuminance of photographing area if the illuminance of photographing area is smaller than or equal to the predetermined reference value; calculating a focus value of each position of the focus lens while driving the focus lens within the predetermined lens-driving range in the unit of a step and selecting a maximum focus value of the predetermined lens-driving range among the calculated focus values, wherein in the calculating of the focus value, the noise level is subtracted from a pixel data that is larger than the noise level and the result of subtracting is used as the pixel data to calculate the focus value.

Abstract: A solid-state image pickup device includes a pixel array section including a plurality of unit pixels, a reference signal production section configured to generate a reference signal and output a detection value, a comparison section configured to compare a reset level upon resetting, a counter configured to start a counting action and continue the counting action to measure a comparison time period in order to obtain count values corresponding to the reset level and the signal level, a detection section configured to retain a result of the comparison of said comparison section when the reset level reaches the detection value as a result of the detection of a black sun phenomenon for a fixed period of time, and a prevention section configured to prevent a black sun phenomenon based on a result of the detection of said detection section.

Abstract: Smear detect circuitry within an analog front end (AFE) of a digital camera determines when black area pixel values received from an image sensor are indicative of smear leakage. Smear leakage can cause a light vertical line in the resulting digital image. When a sensor that is coupled to a storage element is exposed to a bright light source, storage element overload can cause a leakage charge to leak from the storage element to other storage elements along a transfer line. Smear detect circuitry identifies the transfer line exhibiting smear leakage and excludes pixel values from storage elements along that transfer line from the calculation of a black level value used to calibrate color pixel values. The digital camera displays a smear icon indicating smear leakage in a digital image that is to be taken. A digital file of the digital image includes a header with a smear detect field.

Abstract: An image sensing apparatus has an image sensing element for photoelectric conversion, a shutter for selectively creating a light-shielded state and non-light-shielded state for the image sensing element, a bright signal storage unit for storing a bright signal output from the image sensing element in the non-light-shielded state, a dark signal storage unit for storing a dark signal output from the image sensing element in the light-shielded state, an operation unit for subtracting the dark signal from the bright signal to obtain a signal with suppressed dark noise, and a control unit for controlling read of bright and dark signals from the image sensing element in accordance with the relationship between the exposure time of the image sensing element and the photographing time interval.

Abstract: A purpose of this invention is to execute proper smear correction corresponding to the image sensing purpose or condition without degrading the image quality. To achieve this purpose, the smear line signal of an image sensing signal output from a solid-state image sensing element (4) is stored in a smear line memory (7). The value of the smear line signal is limited by a limiting circuit (8), and smear correction is performed for the image sensing signal on the basis of the limited value.

Abstract: In an MOS type solid-state image pickup device in which unit pixels each including a photodiode, a transfer transistor for transferring the signal of the photodiode to a floating node N11, an amplifying transistor for outputting the signal of the floating node to a vertical signal line, and a reset transistor for resetting the floating node are arranged in a matrix form, a P-type MOS transistor is connected between a drain line to which the drain of the reset transistor is connected and a V shift register for selectively supplying the reset voltage to the drain line, and the potential of the floating node is set to the channel voltage of the P-type MOS transistor at the non-selection time.

Abstract: In a digital camera that captures object light through a CCD and creates an image signal, a CPU and a bias controller set an overflow drain voltage when smear is read by a vertical drive section to an overflow drain voltage lower than an overflow drain voltage when a still picture is read. With the above arrangement, there are provided a read controller for an image pick-up device, which can read out a sufficiently large amount of saturated charges from the image pick-up device by suppressing a decrease in an amount of saturated charges even if a voltage fluctuation occurs due to smear read-out, and an image pick-up apparatus that can obtain an image of excellent quality.

Abstract: An imaging apparatus includes: an image sensor with imaging pixels and focus detection pixels arrayed on a plane, which captures an image via an optical system; and a correction unit that corrects image data output from an imaging pixel based upon output data from a focus detection pixel present near the imaging pixel.

Abstract: An electronic camera includes: an image sensor having a charge transfer unit that transfers an electric charge for each pixel column; a correction unit that corrects an electric charge signal outputted from the charge transfer unit using a correction coefficient; and a control unit that controls the correction unit so that the correction coefficient is different according to operational conditions of the image sensor.

Abstract: A circuit and method for correcting pixel output signals for fixed pattern noise. Pixels in a selected row of pixels are read after an integration period and the resulting signals are stored in a first sample and hold circuit for each column. The pixels in the selected row are then reset and immediately read again and the resulting signals are stored in a second sample and hold circuit for each column. The signals in the second sample and hold circuits are subtracted from the signals in the first sample and hold circuits to produce signals related to the light seen by the pixels in the selected row corrected for fixed pattern noise. The output of the first sample and hold circuits and second sample and hold circuits can be connected to a subtraction unit and sequentially activated so that a single subtraction unit is required for the entire imager.

Abstract: An image sensor has at least two photodiodes in each unit pixel. A high dynamic range is achieved by selecting different exposure times for the photodiodes. Additionally, blooming is reduced. The readout timing cycle is chosen so that the short exposure time photodiodes act as drains for excess charge overflowing from the long exposure time photodiodes. To improve draining of excess charge, the arrangement of photodiodes may be further selected so that long exposure time photodiodes are neighbored along vertical and horizontal directions by short exposure time photodiodes. A micro-lens array may also be provided in which light is preferentially coupled to the long exposure time photodiodes to improve sensitivity.

Abstract: An imaging-device driving system, comprising a clock-signal generator, a smear detector, and a frequency-controller, is provided. The clock-signal generator generates a clock signal. The clock signal is used for driving an imaging device. The smear detector detects whether smear is present in an image signal. The image signal is generated by an imaging device. The frequency-controller raises the frequency of the clock signal when the smear detector detects the presence of the smear in the image signal.

Abstract: A number of different elements are added together in a staggered way to avoid the total loss of resolution caused by the binning process. The circuit for doing this includes a variable gain. In a second circuit for carrying this out, to fixed pattern noise reduction circuits are used.

Abstract: A black level correcting device includes: an A/D converting section converting a result of subtracting a feedback signal from an input pixel signal into a pixel value to be output; and a feedback controlling section generating the feedback signal and having a holding section, a feedback gain adjusting section, etc. The holding section clamps a maintaining level to the level of the feedback signal while pixel signals of OB pixels are output, and maintains and outputs the maintaining level while pixel signals of valid pixels are output. The feedback gain adjusting section multiplies the feedback signal by clamp accelerating gain in synchronization with starting readout of the pixel signals from the OB pixels. Accordingly, clamp time of the holding section is shortened, enabling stabilization of the maintaining level at a convergence level before starting readout of the pixel signals from the valid pixels. Consequently, a sag can be reduced.

Abstract: A solid-state imaging device includes: a pixel array unit wherein a unit pixel group with a portion of elements of a unit pixel being shared with a plurality of unit pixels is arrayed in a matrix form, the unit pixel having a detecting unit, a pixel signal generating unit, a transfer unit to transfer the charge, and an initializing unit to initialize the potential of the pixel signal generating unit; and a driving control unit; wherein the driving control unit controls blooming reduction potential which is the transfer control potential supplied to the transfer unit of the unit pixel to be thinned, so that the overflow charge at the detecting unit with the unit pixel to be thinned which has no shared relation with the unit pixel to be read transitions to a state readily transferable to the pixel signal generating unit side of the unit pixel to be thinned.

Abstract: A solid-state image pickup apparatus includes a solid-state image sensor having photosensitive cells and vertical transfer paths. The cells are bidimensionally arranged for converting light incident from a subject via optics to electric charges corresponding to the light to store signal charges. The vertical transfer paths each adjoins the photosensitive cells arranged on a particular column for vertically transferring the signal charges. Before the signal charges are transferred from the cells to the vertical transfer paths, a sweep controller causes unnecessary charges on the vertical transfer paths to be swept out. The sweep controller controls a sweep transfer period necessary for the sweep transfer in dependence upon the amount of the unnecessary charges.

Abstract: An imaging system disables pixel integration for images within frames that are identified as moving while enables pixel integration for images that are not moving. The system may implement a frame-averaging type of integration or recursive types of frame integration, or may refrain from performing frame integration. On a pixel-by-pixel basis, the system may compare a pixel from frame memory with a corresponding pixel of an input frame and may disable pixel integration for the pixel when a difference between the compared pixels exceeds a threshold. One of the integration processes may be performed on the pixels when the difference does not exceed the threshold. When frame integration is disabled or de-selected (e.g., for pixels having motion), the frame memory may be bypassed and a self-integration may be performed with corresponding pixels from a current frame effectively resulting in no integration.

Abstract: A digital camera that captures object light by a CCD to create an image signal includes a read controller that controls reading of light signals from at least two fields of the CCD, in which a field, from which a light signal received by an R-sensor sensitive to red light is read, is separated from a field from which a light signal received by a B-sensor sensitive to blue light is read. The read controller includes: a color temperature discriminating section that discriminates a color temperature based on the light signals received from the CCD; and a read sequence controller that causes a light signal to be read first from the R-sensor when a color temperature is low and causes a light signal to be read first from the B-sensor when the color temperature is high according to a result of discrimination of the color temperature discriminating section.

Abstract: Automatic exposure adjustment control that is not affected by smear. An image pick-up device control system of an electronic shutter, a lens aperture and an automatic gain control. Smear amount is calculated precisely even if weak smear phenomenon does not reach a saturation level. When smear is detected, a first electronic shutter speed and a first lens aperture value are measured and first color information integral values of red, green and blue are measured in a predetermined color measurement area of an effective pixel region of an image pick-up unit. The electronic shutter speed is slowed to a predetermined amount to provide the same exposure as the exposure at the first electronic shutter speed and first lens aperture, and the lens aperture is narrowed only to that amount to measure the second color information integral values of the red, green and blue in the color measurement area. The smear amount is calculated from the color integral values of the red, green and blue.

Abstract: A method of processing noise in image data by an image processor having a signal-processing portion converting an image signal from an image sensor into a digital signal and outputting the converted signal as image data for each frame, the image data indicating sets of pixel values each having a brightness at a corresponding one of coordinate points arranged in directions of rows and columns is disclosed. The method includes the steps of: extracting pixel values; deciding pixel value; finding autocorrelation coefficients of pixel values which are less than a first threshold value; and deciding random noise in the image.

Abstract: A method for blurred image judgment is provided. Firstly, a focus value FV1 of an original image is calculated. By using a blur function, the original image is obfuscated to generate a blurred image, and then the focus value FV2 of the blurred image is calculated. A blur ratio FV1/FV2 is compared with a blur threshold value Tp, thereby discriminating whether the original image is blurred according to the comparing result. The method for blurred image judgment is applicable to a digital image capture device. If the original image is deemed blurred, a blur image signal is issued to notify the user whether the retaking operation is done.

Abstract: An automatic exposure (“AE”), control apparatus to prevent exposure errors resulting from “smear.” Image-capturing is performed at a single exposure time TI (I=1, 2, . . . n); a CCD output is applied with a CCD drive signal to perform an integrating operation for a signal in an AE area using an integration circuit, and then outputs integration value EI+SI at each exposure time. A shutter trigger operation presents readout of an exposure value. An integrator value En+Sn obtained just before the shutter trigger operation, and a smear value Sn? obtained just after the shutter trigger operation are provided to an exposure operation/control circuit. The exposure operation/control circuit then performs an AE operation to receive En+Sn?Sn?En and compares the value to a target value for determining exposure conditions, and provides an AE operation value containing almost no smear component to determine an appropriate exposure condition.

Abstract: In an image reading apparatus using a solid state image pickup element, a smear amount and the total received light amount at whole image taking region of the CCD linear sensor when a light source is turned on without film, are measured and calculated. Using a ratio of the total received light amount when a light source is turned on without film to the one at the time of image reading, a smear correction data of each line is calculated for correction processing.

Abstract: A method of processing image data comprises obtaining a set of weighting coefficients to be used in calculating replacement pixel values associated with defective sensing elements of a detector array, the set of weighting coefficients including at least one negative weighting coefficient, obtaining information identifying one or more defective sensing elements of the detector array, receiving image data from the detector array, calculating a weighted average of pixel values from sensing elements adjacent to a first defective sensing element of the detector array using at least some of the weighting coefficients, and assigning the weighted average to be a replacement pixel value for the first defective sensing element. An apparatus for processing image data according to the method is also described.

Abstract: An image-sensing device has pixel areas for outputting CCD signals of plural channels, and an adjusting portion for adjusting a level of each channel of the CCD signals outputted from the pixel area. A first channel CCD signal is provided from a pixel area 11a, a horizontal OB area 15a, a slide shift area 12a, and an HCCD 13a. A second channel CCD signal is provided from a pixel area 11b, a horizontal OB area 15b, a slide shift area 12b, and an HCCD 13b. Both of the first and second CCD signals are supplied to the adjusting portion with a reference signal added. The adjusting portion controls CCD signal of each channel by making the level of reference signal the same. The variation of the shift efficiency of electric charge in the border of pixel areas 11a and 11b for each channel, and in the slide shift areas 13a and 13b can be compensated.

Abstract: An improved analog-to-digital converter wherein a minimal amount of circuitry is provided for conversion of an analog signal to a series of digital bits. A comparator is provided for generating digital values to which the digital bits correspond. A digital-to-analog converter is provided for generating, via successive approximation, a feedback analog signal based on bits previously generated by the comparator. The analog-to-digital converter compares the feedback analog signal to the input analog signal, and based on the comparison generates a digital value that corresponds to a digital bit. In the method of the invention, an analog signal is converted to a digital value using the analog-to-digital converter, and a digital-to-analog converter comprising two capacitors and a reference selector generates, via successive approximation, a feedback analog signal that is applied to a comparator for comparison to the input analog signal being digitized.

Abstract: The present invention provides an electronic blurring compensation device applied to a digital camera that includes an angular rate sensor for detecting blurring of an image, an solid-state image pickup element for shooting continuously over time a plurality of images, compensating mutual blurring of the plurality of shot images in accordance with the amount of blurring detected by the angular rate sensor, and generating one image by synthesizing the plurality of compensated images, and a CPU for controlling the number of continuous shootings by the solid-state image pickup element such that the total amount of blurring over the plurality of continuously shot images falls within a previously set predetermined value.

Abstract: An aspect of the present invention provides an imaging apparatus comprising: a solid-state image sensor having an effective pixel area and an optical black area; a smear detection device which detects smear intensity and smear occurrence position in a smear occurrence area, in which a smear occurs, in the effective pixel area, based on an output signal obtained from the optical black area of the solid-state image sensor; and a smear correction device which performs smear correction by subtracting a smear correction value corresponding to the smear intensity from an output signal of the smear occurrence area and the vicinity thereof in the effective pixel area.

Abstract: A method to overcome a disadvantage that the signal charges decrease depending upon the storage time in a photo-electric conversion unit of a solid-state image pickup device. At the moment t2 when a prescribed exposure time (t1?t2) passes, the incident light is cut off by a cut off means such as a mechanical shutter of an interlace solid-state image pickup device. Then, at the time t3, a voltage VBsub is applied to N? semiconductor substrate 107 to raise up the potential barrier ?? of the vertical OFD for the signal charges, whereby the leakage of the signal charges due to the self-induced drift, or the thermal diffusion is suppressed. Then, signal charges are read out from the odd lines at the time t4, and signal charges are read out from the even lines at the time t5.

Abstract: Each unit pixel includes a photodiode, a reading selection transistor, a reading transistor, an amplifying transistor, a reset transistor, and a horizontal selection transistor, and thus a MOS image sensor of a dot-sequential reading 5-Tr type is formed. The reading selection transistor and the reading transistor are formed with a two-layer gate structure, and gate potential of the reading selection transistor and the reading transistor is set to a negative potential. Thereby, a lower layer of a gate region of the reading transistor and the reading selection transistor is controlled to a negative potential. Thus, depletion in the lower layer region is suppressed to reduce leakage current.

Abstract: The level of smear charge stored in a CCD is calculated. If the smear level is equal to or greater than a predetermined threshold value, exposure is performed using a mechanical shutter in order to suppress smear. If the smear level is less than the threshold value, exposure is controlled utilizing an electronic shutter. Power consumption owing to drive of the mechanical shutter can be reduced while occurrence of smear is suppressed.

Abstract: An automatic exposure (“AE”), control apparatus to prevent exposure errors resulting from “smear.” Image-capturing is performed at a single exposure time TI (I=1, 2, . . . n); a CCD output is applied with a CCD drive signal to perform an integrating operation for a signal in an AE area using an integration circuit, and then outputs integration value EI+SI at each exposure time. A shutter trigger operation presents readout of an exposure value. An integrator value En+Sn obtained just before the shutter trigger operation, and a smear value Sn? obtained just after the shutter trigger operation are provided to an exposure operation/control circuit. The exposure operation/control circuit then performs an AE operation to receive En+Sn?Sn?En and compares the value to a target value for determining exposure conditions, and provides an AE operation value containing almost no smear component to determine an appropriate exposure condition.

Abstract: The driving device of a solid-state imaging device comprises a driving unit for driving the solid-state imaging device in either an addition driving mode in which a plurality of pixels are added and read as a single pixel or a non-addition driving mode, and a substrate bias voltage supply for applying a bias voltage to the substrate of the solid-state imaging device according to the driving mode. The substrate bias voltage is set according to the number of pixels added in the addition driving mode so that the overflow level of the charge accumulating portion may be lower in the addition driving mode than in the normal driving mode. This suppresses the input of excess charges to the horizontal transfer path even in the addition driving mode, thereby preventing the generation of horizontal streak noise.

Abstract: A method and a system for dynamically detecting and correcting anomalous pixels in the raw data taken from an image sensor array such as a CCD or a CMOS sensor array, thus allowing the use of dumb cameras to capture digital images for subsequent use by an intelligent host—such as being displayed on a computer monitor. This invention uses software algorithms running on an intelligent host processor to dynamically correct the anomalous pixels in the raw data taken from an image sensor array typical of those in a digital still or a video camera. Using the combination of a dumb camera which provides raw data to an intelligent host, which does all the subsequent image processing, the system works by scanning an image frame for pixels that vary more than a specified amount in their brightness value from their neighboring pixels and designating those as defective pixels. The location and frequency of the photosites sending the defective pixels are stored in a statistical database in the computer's memory.

Abstract: A photo-sensor circuit according to an embodiment of the present invention comprises a photo-detecting element (PD) for detecting a light signal and converting the same signal into an electric signal, a first MOS transistor (QT) for charging and discharging parasitic capacitance (C1), a capacitor (C2) for accumulating a terminal voltage of the photo-detecting element as a pixel signal, a second MOS transistor (Q2) for transferring a parasitic capacitance charge from the photo-detecting element to the capacitor (C2), a third MOS transistor (Q3) for amplifying the terminal voltage of the capacitor and a fourth MOS transistor (Q4) for selectively outputting an amplified pixel signal.

Abstract: The invention provides a method and apparatus for reducing image lag in CMOS active pixel sensors at low light levels by controlling the reset level. By ensuring that the reset level is independent of the preceding signal level, the problem of image lag can be avoided. Always resetting a photodiode to a fixed voltage is a hard reset. The maximum signal swing is limited by the reset level and the column readout amplifier. If the column circuits are not modified, using hard reset can reduce the maximum signal swing. However in dark images only a portion of the full scale is used. Therefore the amplifier gain setting can be used to determine whether to use a hard reset or soft reset. This method and apparatus for using hard or soft reset dependent on signal level improves image quality at low light levels without compromising performance at high illumination.

Abstract: In an MOS type solid-state image pickup device in which unit pixels each including a photodiode, a transfer transistor for transferring the signal of the photodiode to a floating node N11, an amplifying transistor for outputting the signal of the floating node to a vertical signal line, and a reset transistor for resetting the floating node are arranged in a matrix form, a P-type MOS transistor is connected between a drain line to which the drain of the reset transistor is connected and a V shift register for selectively supplying the reset voltage to the drain line, and the potential of the floating node is set to the channel voltage of the P-type MOS transistor at the non-selection time.

Abstract: The present invention is directed to a method and apparatus for reading out signals from a MOS image sensor. The invention allows for a relatively high fixed pattern noise canceling rate, even in low light environments. The invention includes a digital processing structure for processing the signals from a pixel array. The pixel array includes a reference row that is formed by being covered by a light shield or black layer to cover the pixels of the reference row from light. The signals from the reference row are converted to digital values and stored in fixed pattern noise storage circuitry. Then, as each of the remaining rows of the pixel array are read out, they are converted to digital values and the digital reference row signals are subtracted therefrom to produce data image signals that are relatively free of fixed pattern noise.

Abstract: In a method for determining the frame rate and exposure time for each frame of a video collection, an image capture system acquires at least two successive frames of a scene, separated in time. The two images are compared to determine if objects in the scene are in motion. If motion is detected, then the speed and displacement of the objects that are moving is determined. If the speed of the fastest moving object creates an unacceptable amount of image displacement, then the frame rate for the next frame is changed to one that produces an acceptable amount of image displacement. Also, if the speed of the fastest moving object creates an unacceptable amount of motion blur, then the exposure time for the next frame is changed to one that produces an acceptable amount of motion blur.

Abstract: An image pickup device comprises a CCD solid-state imaging element composed of a charge accumulation section and a charge transfer section, a CCD driver for driving the imaging element, a mechanical shutter for switching between the transmitting state and shading state of the subject's image on the imaging element, and a controller for controlling the CCD driver and mechanical shutter. The controller, closes, opens and closes the mechanical shutter in that order. After having discharged charges in the first closing, the device refrains from driving the vertical transfer channel during the period that the channel is exposed to light rays and ends exposure in the presence of a charge transfer pulse. Moreover, in a low-speed shutter, the image pickup device switches to exposure end with the mechanical shutter.

Abstract: An anti-blooming charge accumulation pixel using an anti-blooming element coupled to the pixel prevents blooming by ensuring that a voltage of a charge accumulation device of the pixel is always returned to a clamping voltage following comparison events. The anti-blooming element is used to return the voltage across a photodiode to the supply voltage when both a low voltage comparison and a high voltage comparison have occurred. A control block is used to determine an input signal to the anti-blooming element based upon the result of a low voltage comparison and a high voltage comparison. The input signal can be used to drive the anti-blooming element to a desired logic level, thereby causing the voltage across the charge accumulation device to be the clamping voltage. The use of the anti-blooming element eliminates blooming to adjacent pixels, independent of an integration time of the pixel.