Abstract: An image capture apparatus includes an image capture unit having a plurality of exposure adjustment functions including an electronic shutter function for changing an exposure time within a frame period and configured to capture an image of a subject to obtain image data, and an image-capture control unit configured to allow the image capture unit to execute an image capture operation of capturing a plurality of frames of image data having continuity in time at a fixed frame rate and configured to perform exposure adjustment control in accordance with a subject brightness level obtained during the execution of the image capture operation, the exposure adjustment control being performed using preferentially an exposure adjustment function other than the electronic shutter function.

Abstract: During a first horizontal blanking period, signal charges on a first row are transferred from a vertical transfer channel to a line memory. During a second horizontal blanking period, the transferred signal charges are partly transferred from the line memory to a horizontal transfer channel. During a third horizontal blanking period, the remaining signal charges on the first row are transferred from the line memory to the horizontal transfer channel. Thereafter, the signal charges on the second row next to the first row are transferred from the vertical transfer channel to a line memory that is vacant.

Abstract: An imaging device comprises a photoelectric conversion element; first, second, and third capacitors; first, second, third, and fourth charge transfer elements; a reset element; and an amplifier element. The photoelectric conversion element generates an electrical charge according to the amount of received light. The first and second capacitors receive and store the electrical charge. The electrostatic capacity of the second capacitor is lower than that of the first capacitor. The first and second charge transfer elements transfer the electrical charge to the first and second capacitors simultaneously. The third capacitor receives the electrical charge stored in the first or second capacitor. The electrical potential of the third capacitor varies according to the received electrical charge. The third and fourth charge transfer elements transfer the electrical charge stored in the first and second capacitors to the third capacitor separately.

Abstract: The signal processing circuit of the present invention comprises a drive unit and a processing unit for picture signal. The drive unit supplies each of the shift pulses separately to the electronic shutter shift register and the readout shift register. The processing unit for picture signal designates a control start position of a digital picture signal outputted from an A/D converter and performs interpolation processing thereon along the horizontal direction and the vertical direction. The drive unit adjusts cycles of each of the shift pulses for controlling a vertical-line readout rate of the solid-state imaging device, and then intermittently reads out the analog picture signal from the solid-state imaging device. The processing unit for picture signal performs vertical-line interpolation processing in accordance with the vertical-line readout rate for extending a part of picture area of the digital picture signal.

Abstract: An optical pointing device and a method of adjusting an exposure time and a comparison voltage range of the optical pointing device are provided. The optical pointing device obtains a high-resolution image using a low-resolution analog-to-digital (A/D) converter, and calculates a movement value using the obtained image. Thus, the optical pointing device can calculate an accurate movement value, reduce production cost, and provide a rapid operating speed and low power consumption. Further, the optical pointing device can use the A/D converter having a relatively low signal-to-noise ratio of an input signal.

Abstract: A CMOS imaging system with increased charge storage capacitance of pixels yet decreased physical size, kTC noise and active area. A capacitor is linked to the transfer gate and provides a storage node for a pixel, allowing for kTC noise reduction prior to readout. The pixel may be operated with the shutter gate on during the integration period to increase the amount of time for charge storage by a pixel.

Abstract: A method of obtaining an image uses a broad dynamic range image sensor that includes a photosensitive cell formed of pixels. Each pixel includes a element, a first initialization transistor series connected to the element, storage means coupled to the element, a third initialization transistor series connected to a capacitor, and fourth and fifth series connected transistors, wherein one control terminal of the fourth transistor is connected to the capacitor. The method comprises initializing the capacitor and t-he-photodiode to a first initialization voltage via conduction of the second and third transistors, then making the second transistor non-conductive to start a first long exposure period of the photodiode. At the end of the first exposure period, the first transistor is made conductive to initialize the photodiode to a second initialization voltage to start a second short exposure period. The photodiode voltage level is stored in the capacitor.

Abstract: A solid-state imaging apparatus including: a pixel section having two-dimensionally arrayed pixels each having a first photoelectric conversion device and a second photoelectric conversion device located at positions regarded as the same position at which image is formed by an imaging optical system and a means for independently resetting each of signals accumulated at the first photoelectric conversion device and the second photoelectric conversion device; a reset control means for executing a resetting of the signal of all first photoelectric conversion devices of the pixel section as a first resetting operation, and executing, after a desired exposure time subsequent to the first resetting operation, a resetting of the signal of all second photoelectric conversion devices of said pixel section as a second resetting operation; a read means for reading simultaneously or almost simultaneously signals of the first photoelectric conversion device and the second photoelectric conversion device of each pixel star

Abstract: Disclosed is a method for managing a DSS (Digital Slow Shutter) mode in a monitoring camera. When an iris of the monitoring camera is maximally opened and a shutter speed is minimum, the DSS mode is set. In the DSS mode, a video frame inputted in a predetermined cycle is stored in a memory. A plurality of video frames stored in the memory are synthesized into a monitoring video frame. The monitoring video frame is outputted irrespective of a luminance thereof. When the memory is full of the video frames, an oldest stored video frame is replaced with a newly inputted video frame. The monitoring video frame can be consecutively outputted in a predetermined cycle even though the monitoring camera operates in the DSS mode. The monitoring video frame based on a bright luminance level can be outputted, such that a monitoring function is enhanced.

Abstract: In a moving image recording process, a shooting operation using a short exposure time appropriate for shooting a still image, and a shooting operation using a long exposure time appropriate for shooting a moving image are performed repeatedly in turn. Plural pieces of frame image data “B” shot by the shooting operations using a long exposure time are successively recorded as moving image data. When a shutter button is pressed in the moving image recording process, frame image data which is shot using a short exposure time just before the shutter button is pressed is recorded as a still image.

Abstract: An image processing circuit capable of shooting a desired subject is provided in which increasing the size of the digital camera has been avoided. Sensor control unit 31 includes a moving image mode and a still image shooting mode. If a shutter button is operated when sensor control unit is driven in the moving image mode in which mechanical shutter 21 is open, image pickup control unit 37 stops the operation of sensor control unit. Then, after exposing image sensor 23 for a predetermined exposure time, image pickup control unit 37 closes mechanical shutter 21. Additionally, image pickup control unit 37 switches sensor control unit 31 to the still image shooting mode while mechanical shutter 21 is closed.

Abstract: A backside illuminated imaging sensor pixel includes a photodiode region, a pixel circuitry region, and a storage capacitor. The photodiode region is disposed within a semiconductor die for accumulating an image charge. The pixel circuitry region is disposed on the semiconductor die between a frontside of the semiconductor die and the photodiode region. The pixel circuitry region overlaps at least a portion of the photodiode region. The storage capacitor is included within the pixel circuitry region overlapping the photodiode region and is selectively coupled to the photodiode region to temporarily store image charges accumulated thereon.

Abstract: A shutter system for a pixel array is disclosed. The system includes a read shift register, first and second reset shift registers, and a plurality of logic gates. The read shift register is configured to sequentially count rows of the pixel array from top to bottom, such that the read shift register generates a read pointer. The first reset shift register is configured to sequentially reset rows of the pixel array from top to bottom. The first reset shift register provides a first reset pointer for allowing reset of pixels in a row indicated by the first reset pointer. The first reset pointer allows reset of pixels prior to reading of the pixels in a row indicated by the read pointer. The time difference between the first reset pointer and the read pointer indicates an exposure time.

Abstract: A method for capturing an image using an image capturing module with multiple pixels configured in a 2-dimensional matrix and a focal plane electronic shutter function which sequentially slides the exposure timing by constant interval by pixel group which is a unit of predetermined number of the pixels while scanning; the method includes an image data input process for detecting shutter operation, obtaining a reference image while skipping one or more of the pixel groups by sequentially sliding the exposure timing by the constant interval, and obtaining a target image while not skipping pixel groups to be captured, a motion data detection process for calculating the motion data of the target image based on the reference image, and a distortion compensation process for compensating for distortion in the target image according to the motion data.

Abstract: A method for obtaining an image having a plurality of exposure regions is described. The method includes exposing first and second regions of an image sensor, reading out first image data from the first region, pausing a clock signal to the image sensor after the reading out of the first image data, resuming the clock signal to the imaging module, and reading out second image data from the image sensor for the second region of the image. A graphics controller and imaging device for capturing images having multiple exposure regions are also described.

Abstract: An electronic image stabilizer in a digital camera compensates for camera motion-induced blurriness by segmenting exposure times into multiple shorter exposure times and summing the individual pixels from successive frames after applying an appropriate motion correction. Motion is detected by computing the correlation function between successive images, and compensation is applied by maximizing the correlation function. This avoids the need for mechanical stabilization devices in order to detect or correct the motion as is done in prior art. This method further enables the detection of moving objects in a still background, and correction of blurriness images due to such motion.

Abstract: An imaging device includes a MOS image sensor that shoots an image of a subject, and a control unit that selects one of plural shutter drive modes and drives the MOS image sensor in the selected shutter drive mode. The control unit analyzes a through image of a subject that is obtained by the MOS image sensor before main shooting (step S3) and performs the selection automatically based on a result of the analysis (steps S6, S9, and S10).

Abstract: A pixel array uses two sets of pixels to provide accurate exposure control. One set of pixels provide continuous output signals for automatic light control (ALC) as the other set integrates and captures an image. ALC pixels allow monitoring of multiple pixels of an array to obtain sample data indicating the amount of light reaching the array, while allowing the other pixels to provide proper image data. A small percentage of the pixels in an array is replaced with ALC pixels and the array has two reset lines for each row; one line controls the reset for the image capture pixels while the other line controls the reset for the ALC pixels. In the columns, at least one extra control signal is used for the sampling of the reset level for the ALC pixels, which happens later than the sampling of the reset level for the image capture pixels.

Abstract: This development is about the camera control method for a vehicle license plate recognition system. In detail, it is about the applying variable shutter speed and gain level per image frames that are captured through a CCTV camera of vehicle license plate recognition system. The entire control is done through 3 steps. The first step is to build up a lookup table of electronic shutter speed and gain level to generate images of various brightness levels and archive the created lookup table on to a memory of a camera. The second step is to calculate the average value of image brightness and write the multiple parameters of electronic shutter speed and gain level that match with the calculated average brightness value in the lookup table to a camera control register. The third step is to output series of images of various brightness that are captured under various shutter speeds and gain levels by the control from the camera register.

Abstract: A method of forming an image of a moving object is provided. The method includes capturing a first digital image of a moving object using a first rolling shutter scanning in a first direction. Likewise, a second digital image of the moving object is captured using a second rolling shutter scanning in a second direction different from the first direction. The first and second digital images are processed to form a composite digital image of the moving image.

Abstract: An image pickup apparatus has a solid-state image pickup device which outputs a charge signal according to a timing signal, a sampling unit which samples the charge signal in response to the timing signal, an A/D converting unit which converts a sample signal to a digital signal in response to the timing signal, and a timing unit which, in response to the number of first clocks in a horizontal period of the timing signal when a picture signal is outputted at a first frame rate (60 fps), generates a timing signal having the number of clocks in the horizontal period higher than the number of the first clocks, and supplies a timing signal based on the generated timing signal, the sampling unit, and the A/D converting unit in case of a second frame rate (50 fps) lower than first frame rate.

Abstract: Disclosed herein is an electronic camera for generating an image having a wide dynamic range by synthesizing two image pickup signals of different exposure amount generated by using an electronic shutter function and means for shutting off light, shading of image pickup signals resulting from difference in charge accumulating time among the pixels of image pickup device due to operation from opened state to closed state of the means for shutting off light being corrected by a shading correction means to form a synthesized image without an occurrence of false color due to shading.

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

Abstract: A CMOS imaging system with increased charge storage capacitance of pixels yet decreased physical size, kTC noise and active area. A capacitor is linked to the transfer gate and provides a storage node for a pixel, allowing for kTC noise reduction prior to readout. The pixel may be operated with the shutter gate on during the integration period to increase the amount of time for charge storage by a pixel.

Abstract: By providing dummy pixels separately from effective pixels, the total number of pixel rows is equalized with the number of horizontal sync signals included in one frame interval (which is called an “HD number”). A period during which a reset signal for an electronic shuttering operation is being supplied to an arbitrary pixel row overlaps with a period during which another pixel row is selected to perform a readout operation thereon. Thus, it is possible to suppress a variation in reset potential among effective pixels.

Abstract: CMOS image sensor with a rolling shutter that uses two separate clocks. One of the clocks is used during normal operation. When timing is changed, the other clock is started and used during an interim period to avoid distortion in the image. After that interim period, the new clock timing is coupled to the original clock circuit.

Abstract: In an XY address type solid-state imager apparatus comprising a solid-state imager having a plurality of pixels two-dimensionally arranged, and horizontal and vertical scanning circuits to read signals of the pixels, the scanning circuits each have a progressive scanning circuit to progressively read pixel signals by a first scanning control signal, and an interlace scanning circuit to read pixel signals with an interlaced manner by a second scanning control signal different from the first scanning control signal, and arbitrarily carries out combining of progressive reading and interlace reading in one frame in accordance with a combination of the respective scanning control signals, and reads pixel signals.

Abstract: A method and apparatus are provided for operating a camera. The method includes the steps of providing an array of image sensing pixels, disposing an electronic shutter in an optical path between the array of pixels and an image where the electronic shutter has a reflective state and a transmissive state and applying a predetermined sequence of electrical signals to the electronic shutter to expose the image sensing pixels to the image.

Abstract: An illumination-component extractor (illumination component extraction section) extracts an illumination component Log from a picked-up image (original image picked up an image sensor having a photoelectric conversion characteristic which comprises a linear characteristic region and a logarithmic characteristic region. A reflectance component determiner (subtraction section) extracts a reflectance component Log (R1). A compressor (illumination component compression section) subjects at least the illumination component Log of the logarithmic characteristic region to DR compression. Image production mean (image production section) produces a new image (synthetic image) based on the DR-compress illumination component and the reflectance component.

Abstract: An image capture device includes a light source, an image capture unit, a brightness detector, an object distance obtaining unit which obtains an object distance to the object, first and second controllers, and an amplifier which amplifies an image signal output from the image capture unit by an amplifying factor according to a sensitivity set by one of the first and second controllers. The first controller disables the light source and sets a sensitivity which is in accordance with the brightness of the object and which is lower than a predetermined sensitivity. The second controller enables the light source and sets a sensitivity which is lower than the predetermined sensitivity. The second controller includes a sensitivity obtaining unit which obtains a sensitivity according to the object distance and a maximum amount of light emitted from the light source, and a setting unit which sets the obtained sensitivity.

Abstract: There is disclosed a photographic device that uses an image sensor and an electronic viewfinder. When a release button is pressed halfway, an aperture value, an electronic shutter speed and a photosensitivity are decided based on the present subject brightness to provide a proper exposure value for photographing a still image. So long as the release button is kept being pressed halfway, a timing generator drives the image sensor to shoot video images at a frame rate of 20 Hz, and the aperture value decided for still image photography is fixed, whereas the electronic shutter speed and the photosensitivity are adjusted according to the subject brightness by use of an aperture-priority type video program. When the release button is pressed to the full, an exposure for a still image is done with the fixed aperture value.

Abstract: A solid-state imaging device is provided in which noise caused by fluctuation of potential of a readout pulse is prevented from being superposed on the amount of signal charges even if the potential of the readout pulse fluctuates. The solid-state imaging device includes: a semiconductor substrate having a charge-storage region and a signal readout circuit having a charge coupled element; and a photoelectric conversion film converting incident light into signal charges in accordance with the intensity of the incident light, the signal charges being accumulated in the signal charge-storage region and read out by the signal readout circuit; and a potential barrier unit provided around a connection portion for passing the signal charges through the signal charge-storage region so that the potential barrier unit serves as a potential barrier against charges in the wiring connection portions.

Abstract: An imaging device that realizes a rolling shutter by performing reset, exposure, and read-out for respective lines sequentially, the imaging device including a reset unit that resets plural lines simultaneously.

Abstract: A method for capturing a sequence of images, the method includes the steps of capturing a first image on an image sensor having a plurality of photosensitive areas having a first portion of photosensitive areas and a second portion of photosensitive areas; transferring the first portion of the first captured image to a first plurality of storage mechanisms; capturing a second image on the image sensor; transferring the second portion of the second captured image to a second plurality of the storage mechanisms; capturing a third image on the image sensor; reading out the first portion of the first captured image from the first plurality of storage mechanisms and reading out the second portion of the second captured image from the second plurality of storage mechanisms; and reading out the third image.

Abstract: A solid-state imaging device according to the present invention includes: a plurality of photoelectric conversion units each of which generates a signal corresponding to the quantity of incident light; a plurality of readout units which read out the signals generated by the photoelectric conversion units; transfer paths which transfer the signals read out by each of the readout units; an output unit which outputs each of the signals transferred from the readout units via the transfer path; and a generation unit which generates a constant reference signal, in which the reference signal is outputted from the output unit via at least a part of the transfer path.

Abstract: The invention provides a field sequential color camera system wherein a light-emitting strobe or diode with invisible light such as infrared or ultraviolet light added to red, green and blue visible light is combined with an illumination unit capable of emitting light in a field sequential mode so that high-definition images are finished and obtained at two frames.

Abstract: A solid-state imaging device 5 includes photoelectric conversion elements 51R, 51G, 51B; and photoelectric conversion elements 51r, 51g, 51b. An exposure period for the photoelectric conversion elements 51r, 51g, 51b is controlled shorter than that for the photoelectric conversion elements 51R, 51G, 51B. During the exposure period for the photoelectric conversion elements 51R, 51G, 51B, an imaging device driving section 10 applies a readout pulse to transfer electrodes V2, V6, reads out electric charges accumulated in the photoelectric conversion elements 51r, 51g, 51b into vertical electric charge transfer paths 54, and controls to start exposure of the photoelectric conversion element 51r, 51g, 51b. During a period from start of the exposure of the photoelectric conversion elements 51R, 51G, 51B to the applying of the readout pulse, the imaging device driving section 10 applies a transfer pulse of a low level to the transfer electrodes V1 to V8.

Abstract: A method and apparatus of combining multiple exposure images by applying a transfer function to pixel output signals from pixels in a pixel array, the pixel output signals from each pixel including at least a first pixel output signal generated in response to a first exposure time and a second pixel output signal generated in response to a second exposure time.

Abstract: An imaging system comprises a rolling-reset imager that forms an electronic image of an object, a light source illuminating the object with pulsed light, and a bandpass optical filter disposed between the object and the rolling-reset imager. The pulsed light has an illumination frequency spectrum and an illumination pulse width defining an effective exposure time for forming the image of the object. The bandpass optical filter has a frequency pass band permitting transmission of a significant portion of the illumination frequency spectrum while at least approximately inhibiting transmission of at least some light having frequencies outside the illumination frequency band.

Abstract: A digital camera takes interleaved photographs of two different kinds. In one example embodiment, the first kind of photograph is taken using a first set of pixels of the camera's electronic array light sensor and has a short exposure time. The second kind of photograph is taken using a second set of pixels and has a long exposure time. More than one of the short-exposure-time photographs is taken while each long-exposure-time photograph is exposed. The two kinds of photographs are used for different purposes. For example, one kind may be used for performing automatic focusing while the other kind is used for displaying in a live view display. In this way, live view may continue while automatic focusing is performed. In another embodiment, one kind of photograph is used for providing a live view display, and the other is used in selecting exposure settings for a final photograph.

Abstract: Devices, systems, and methods for controlling a shutter of a still or video camera or cellular telephone, to reduce blurring due to motion of vibrations are disclosed. The control device includes an inertial sensor for measuring acceleration, velocity and/or angular rotation and for providing data therefrom and a controller for calculating an acceleration amplitude and frequency for predicting the time between acceleration maximums. The controller opens and closes the camera shutter at a time corresponding to the predicted time between maximum accelerations as measured from a real-time acceleration maximum, negating the need for post-imaging correction.

Abstract: A new adaptive pixel architecture, folded-multiple-capture (FMC), integrates synchronous self-reset and multiple capture schemes and advantageously eliminates the requirement of a high-frame-rate sensor array, which is essential for conventional image sensors with high dynamic range. The FMC comprises a per-pixel analog-front-end (AFE), a fine analog-digital convertor (ADC) stage, and a digital-signal-processor/controller (DSPC) stage. The AFE performs programmable gain control, synchronous self-reset, sample-and-hold, and enables disturbance detection. In the AFE, a comparator compares an integrator output with a threshold voltage and produces a binary sequence accordingly. The ADC utilizes the binary sequence and the folded multiple capture signals to estimate photocurrent.

Abstract: An image processing apparatus for applying effects to a stored image includes an optical reader. The apparatus includes a feed mechanism for feeding a planar element on which a printed, two-dimensional pattern having a certain resolution is carried, to the reader. The reader has a sensor with a resolution capacity of at least twice the resolution of the two-dimensional pattern and is configured to generate program data represented by the two-dimensional pattern in an external format, the data itself representing an image processing program. A reader interface is connected to the reader to receive the program data from the reader, the reader interface being configured to transform the program data to an internal format suitable for processing. A processor is connected to both the reader and the reader interface to control operation of the reader and the reader interface and to apply the image processing program to the stored image to generate an output image with desired effects.

Abstract: An image apparatus and method is disclosed for extending the dynamic range of an image sensor. A first linear pixel circuit produces a first pixel output signal based on charge integration by a first photo-conversion device over a first integration period. A second linear pixel circuit produces a second pixel output signal based on charge integration by a second photo-conversion device over a second integration period, where the second integration period is shorter than the first integration period. A sample-and-hold circuit captures signals representing the first and second pixel output signals.

Abstract: A method for driving a solid state imaging device which prevents the generation of electronic shutter noise even when the integration time for exposure of a pixel region fluctuates. The solid state imaging device performs a rolling shutter operation that sequentially selects a reset row and a read row separated from each other in accordance with a row spacing based on integration time in the pixel array. A dummy row is selected when a reset row or a read row is not selected. The method includes selecting a dummy reset row so that the total of the number of the reset rows and the reset dummy rows that are simultaneously selected is constant regardless of the number of simultaneously selected reset rows.

Abstract: The effective photosensitive area of a solid-state photosensor is controlled with a multitude of electrodes (E1, . . . , Ei, . . . , En) on top of an insulator layer (O) covering a semiconductor substrate (S). Photogenerated charge carriers move laterally under the influence of the voltage distribution on the various electrodes (E1, . . . , Ei, . . . , En), and they are collected at the two ends of the photosensor in diffusions (D1, D2). The voltage distribution on the electrodes (E1, . . . , Ei, . . . , En) is such that the voltage at the two furthermost electrodes (E1, En) is maximum (if photoelectrons are collected), minimum at an interior electrode (Ei), and monotonously decreasing in between. The lateral position of the electrode (Ei) with minimum voltage defines the effective photosensitive area of the photosensor.

Abstract: Exposure adjustment methods and systems are provided. First, image data including a plurality of pixels is obtained. A plurality of sample regions is set based on respective pixels. A parameter calculation is performed according to a plurality of specific pixels in the sample regions to obtain a plurality of groups of adjustment parameters. At least one of the pixels is performed with a parameter adjustment according to the adjustment parameters.

Abstract: The present invention enables prevention of influence of a trigger pulse in an image from an image pickup apparatus, with a simple structure and irrespective of exposure time and the cycle of the trigger pulse.

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: A new adaptive pixel architecture, folded-multiple-capture (FMC), integrates synchronous self-reset and multiple capture schemes and advantageously eliminates the requirement of a high-frame-rate sensor array, which is essential for conventional image sensors with high dynamic range. The FMC comprises a per-pixel analog-front-end (AFE), a fine analog-digital convertor (ADC) stage, and a digital-signal-processor/controller (DSPC) stage. The AFE performs programmable gain control, synchronous self-reset, sample-and-hold, and enables disturbance detection. In the AFE, a comparator compares an integrator output with a threshold voltage and produces a binary sequence accordingly. The ADC utilizes the binary sequence and the folded multiple capture signals to estimate photocurrent.