Abstract: An image capturing apparatus includes a shutter-operation accepting unit that accepts a shutter operation; an image capturing unit that captures an image of an object and generates a captured image; a brightness-information extracting unit that extracts, from the captured image, brightness information indicating brightness of the whole captured image; a luminance-value-distribution-information extracting unit that extracts, from the captured image, luminance-value-distribution information indicating a distribution of luminance values in the captured image; a scene determining unit that determines a scene of the object included in the captured image based on the extracted brightness information and luminance-value-distribution information; and a control unit that performs control to record captured images using at least two different image capturing/recording parameters if, when the shutter operation has been accepted, the scene of the object included in the captured image is determined to be a predetermined s

Abstract: A portable digital image acquisition device includes multiple lenses and/or multiple flashes. A main digital image and first and second reference images are acquired. The first and second reference images are acquired with different flash-lens combinations that have different flash-lens distances. One or more flash eye defects are detected and corrected in the main image based on analysis of the first and second reference images.

Abstract: A light leakage compensating unit image sensor in a back side illumination method includes a photodiode and a storage diode, in which light input to a back side of the unit image sensor is received only by an area forming an electrode of the photodiode, and an area for forming another electrode of the photodiode and an area for forming two electrodes of the storage diode are separated from each other by a well, thereby compensating light leakage.

Abstract: There is provided an imaging apparatus including an optical elements that disperses an incoming light from a subject into a first light composed of wavelength components in a visible light region only, and a second light which does not contain the first light and which is composed of wavelength components in other than visible light region only, a color image pickup device that receives the first light irradiated from the optical element, and a monochrome image pickup device that receives the second light irradiated from the optical element.

Abstract: A method of generating a high dynamic range image corresponding to a specific scene. The method includes shooting a specific scene to generate a base image; selecting a bright area and a dark area from the base image; determining base luminance according to the base image; shooting the specific scene to generate at least a first image, wherein average luminance of a part of the first image corresponding to the bright area of the base image is less than or equal to the base luminance; shooting the specific scene to generate at least a second image, wherein average luminance of a part of the second image corresponding to the dark area of the base image is greater than or equal to the base luminance; and combining at least the first image and the second image into a high dynamic range image corresponding to the specific scene.

Abstract: An electronic camera includes an imager. An imager, having an imaging surface capturing a scene, outputs an image. A specific key is transitioned among a non-operated state, a first operated state and a second operated state. A sensor senses the specific key being transitioned from the non-operated state to another state. A setter sets a reference indicating a magnitude different depending on a state of the specific key, in response to a sensing of the sensor. An adjuster adjusts an imaging condition based on the image outputted from the imager. A controller determines whether or not a variation of the scene captured by the imaging surface exceeds the reference set by the setter, so as to permit an adjusting process of the adjuster corresponding to a positive determined result while restrict the adjusting process of the adjuster corresponding to a negative determined result.

Abstract: A digital image capture device and a brightness correction method thereof are described. The digital image capture device is adapted to correct the brightness value of a shot object in a digital image through the compensation of a strobe during shooting. The method includes setting a shooting magnification of the digital image capture device to the shot object; capturing a pre-shot image at least including the image of the shot object; triggering a strobe to emit a main flash onto the shot object, so as to shoot a digital image; setting a plurality of light measuring areas in the digital image; calculating a corresponding object distance of the shot object from each of the light measuring areas; establishing a shading table according to each of the object distances; and loading the shading table to adjust the brightness value of each of the light measuring areas in the digital image.

Abstract: In a particular embodiment, a method is disclosed that includes illuminating an opaque mask having a plurality of holes formed therein, each hole of the plurality of holes having a predetermined size. The method includes forming a two-dimensional impulse response image of the illuminated opaque mask using a camera module. The method further includes determining at least one optical characteristic of the camera module based on the two-dimensional impulse response image of the illuminated opaque mask.

Abstract: An image pickup apparatus is provided which informs a user of a state of brightness adjusting operation and which has excellent usability for the user. Disclosed is a digital camera including an image adder 5d for synthesizing a plurality of continuously taken image frames to produce a synthesized image, an image processing apparatus 5 for executing image brightness adjusting processing for synthesizing a required synthesis number of image frames and adjusting brightness of the synthesized image at the time of continuous picture-taking of a subject, and a display device for displaying an image which is being synthesized by the image adder in the image brightness adjusting processing.

Abstract: A method for automatically controlling image brightness in an image photographing device by calculating a histogram for an image; obtaining a brightness average for the histogram; determining if a number of pixels of a histogram distribution within a first range and a number of pixels of a histogram distribution within a second range are included within a preset range; and when the number of pixels of the histogram distribution within the first range and the number of pixels of the histogram distribution within the second range are included within the preset range, as a result of a determination, adjusting the brightness average to be a reference brightness.

Abstract: A triggering system and process for a form reader is shown using a histogram of the optical scene. The form reader is open on three sides with a camera facing a platen on to which a form is placed. The camera converts the light rays reflected from the platen into a video stream that is sent to a processor. A change in content of a first light intensity level contrasted to the content of a second light intensity level is used to determine when the form enters the scene. Illustratively, the first light intensity level represents black levels and the second light intensity levels represent white levels. A threshold is pre-determined that isolates the first light intensity content, and when the first light intensity content remains constant (after the presence of a form) the form is deemed to be still wherein the system may then read the information on the form.

Abstract: An aspect of the present invention features an apparatus for compensating color deviation of an image that has uneven color deviation.

Abstract: An imaging apparatus includes a solid-state imaging device, a derive section and a signal processing section. The imaging device includes plural pixels arranged on a surface of a semiconductor substrate. The pixels include plural chromatic color pixels for plural colors and plural high-sensitivity pixels having a higher sensitivity to incident light than the chromatic color pixels. The drive section controls the imaging device to simultaneously start exposing the chromatic color pixels and exposing the high-sensitivity pixels, to read first signals from the high-sensitivity pixels during an exposure period, respectively and hold the read first signals, thereafter, to read second signals from the high-sensitivity pixels, respectively, and to read third signals from the chromatic color pixels, respectively. The signal processing section produces color image data based on the first signals, the second signals and the third signals.

Abstract: A method for displaying or capturing an image comprises directing an illumination beam onto a mirror of a highly resonant, mirror-mount system and applying a drive signal to a transducer to deflect the mirror. In this method, the drive signal has a pulse frequency approaching a resonance frequency of the mirror-mount system. The method further comprises reflecting the illumination beam off the mirror so that the illumination beam scans through an area where the image is to be displayed or captured, and, addressing each pixel of the image in synchronicity with the drive signal to display or capture the image.

Abstract: An image processing system is adapted to compress a captured image having a plurality of regions of interest (ROIs). The image compression device includes an image dividing unit, a resolution distribution unit and an encoder. The image dividing unit divides the captured image into a number of blocks according to a predetermined size. The resolution distribution unit distributes a display resolution to each ROI of the captured image according to predetermined display information which includes a position and a resolution level of each ROI. The resolution distribution unit further obtains the blocks covered by each ROI according to the position of each ROI. The encoder separately encodes each block in the captured image according to the resolution level of each block using predetermined rules to obtain compression strings of each block, and generates compression image based on the compression strings and the predetermined display information.

Abstract: An imaging apparatus includes an imaging device, a first luminance signal generating unit and a correcting unit. The imaging device includes at least three types of color detecting photoelectric converting elements and a luminance detecting photoelectric converting element. The first luminance signal generating unit generates a first luminance signal corresponding to the color detecting photoelectric converting element from a color signal obtained from each of the at least three types of color detecting photoelectric converting elements. The correcting unit corrects, based on the color signal, at least a second luminance signal corresponding to the luminance detecting photoelectric converting element which is obtained from the luminance detecting photoelectric converting element so as to generate a luminance signal which constitutes image data corresponding to each of the photoelectric converting elements.

Abstract: Provided is a method for correcting a bad pixel in an image sensor. The method includes a first step of creating and storing a plurality of image frames of an object; a second step of scanning pixels in the image frames; a third step of storing, when a bad pixel is detected in the image frames, the location of the bad pixel as a bad block location in a memory; and a fourth step of correcting the luminance value of the bad block by calling the bad block location stored in the memory in an image capture operation.

Abstract: A storage portion stores, in association with first pixel values, table values including either gamma-corrected values obtained by performing gamma correction on the first pixel values using a predetermined reflectance component or second pixel values calculated based both on the gamma-corrected values and on the first pixel values. A pixel-value generating portion includes an extracting portion and a determining portion. The extracting portion extracts at least one of the table values corresponding to a pixel value of a subject pixel. The determining portion determines a pixel value of an output image based on the at least one of the table values extracted by the extracting portion. The predetermined reflectance component is the reflectance component calculated by the reflectance-component calculating portion when the pixel value of the subject pixel is substantially identical with the average luminance of the peripheral pixels.

Abstract: There is described an image capturing apparatus, which makes it possible to conduct a high-accurate range finding operation irrespective of the position of the subject. The apparatus, comprises: a plurality of imaging elements; a plurality of luminance signal generating sections, each of which generates a luminance signal by mixing the plural wavelength signals with each other at a predetermined mixture ratio; a plurality of mixture ratio controlling sections, which respectively correspond to the plurality of imaging elements, and each of which changes a mixture ratio, at which the plural wavelength signals are mixed with each other, based on a positional relationship between a corresponding one of the plurality of imaging elements and a subject; and a range detecting section to detect a distance to the subject, based on a correlation between luminance signals, each of which is the luminance signal generated by each of the luminance signal generating sections.

Abstract: An electronic camera includes an imager. An imager repeatedly outputs an image representing a scene captured by an imaging surface. An adjuster adjusts an imaging condition by referring to any one of a plurality of adjustment references including a specific adjustment reference suitable for outdoors. A controller controls whether or not the referring by the adjuster to the specific adjustment reference should be permitted, with reference to a determined result of whether or not an average luminance of the image outputted from the imager satisfies a first condition and a determined result of whether or not a ratio of an area having a luminance deviating from a predetermined range occupying in the image outputted from the imager satisfies a second condition.

Abstract: A color imaging device comprises: one or more arrays (10, RA, GA, BA) of color selective photodetectors (R, G, B) configured to acquire a color image of a subject; a set of avalanche photodiode photodetectors (APD) arranged to acquire a luminance image of the subject; and digital image processing circuitry (30) configured to process the acquired color image and the acquired luminance image to generate an output image of the subject. In some embodiments the avalanche photodiode photodetectors are configured to perform photon counting. In some embodiments, the one or more arrays comprise an imaging array (10) including the color-selective photodetectors (R, G, B) distributed across the imaging array with the set of avalanche photodiode photodetectors (APD) interspersed amongst the color-selective photodetectors.

Abstract: A bright luminance value, a dark luminance value, and an average luminance value relating to a face image portion included in an image represented by fed image data are calculated in calculating circuits. Further, a target bright luminance value and a target dark luminance value are calculated in a calculating circuit on the basis of a target average luminance value and a dynamic range that are inputted from an input device and the calculated bright luminance value, dark luminance value, and average luminance value. Interpolation processing based on a correspondence between the calculated bright luminance value, dark luminance value, and average luminance value relating to the face image portion and the target bright luminance value, the target dark luminance value, and the target average luminance value respectively corresponding thereto is performed in a corrected value calculating circuit, to create a look-up table.

Abstract: An imaging apparatus for capturing a moving image performs backlight correction of an image and outputs a natural image. The imaging apparatus electronically captures an image of a subject. An optical system has a light amount adjustment function. An imaging unit reads an optical image of the subject that is formed by the optical system. An A/D converter subjects an output of the imaging unit to A/D conversion. A backlight correction unit converts the tones of an image read by the A/D converter using a conversion characteristic selected differently according to a spatial position and at least increases the luminance level of a dark region of the image. An instruction unit instructs to start backlight correction. A control unit operates the backlight correction unit based on an instruction signal output from the instruction unit, and decreases an exposure light amount of the optical system by a predetermined amount.

Abstract: A photometric device includes a storage-type photometric sensor, a first control means that performs accumulation control on the photometric sensor based upon an average value of an output of the photometric sensor, a second control means that performs accumulation control on the photometric sensor based upon a maximum value of the output of the photometric sensor, and an accumulation control means that controls the second control means to perform next accumulation control, if the maximum value of the output of the photometric sensor on which the accumulation control is performed by the first control means exceeds a saturation output level of the photometric sensor, and controls the first control means to perform next accumulation control, if the maximum value of the output of the photometric sensor does not exceed the saturation output level of the photometric sensor.

Abstract: Whether a pixel of interest contained in applied image data exhibits color bleed (a false color or purple fringe) is determined. If the pixel of interest is determined to exhibit color bleed, a direction along which luminance is monotonically decreasing in the vicinity of the pixel of interest is discriminated using the pixel of interest as a starting point. A search is performed in the direction of monotonically decreasing luminance to find a pixel where the monotonic decrease in luminance ends. The found pixel where the monotonic decrease in luminance ends is decided upon as a target pixel and a correction value for causing the color of the pixel of interest to match the color of the target pixel is calculated. The color of the pixel of interest is corrected using the calculated color correction value.

Abstract: An apparatus and a method for processing an image. The method includes: increasing contrast of an input image to generate a first image; adding a mask having a pattern showing an image effect, to the first image to generate a second image; and adjusting a range of pixel values of the second image to generate a resultant image.

Abstract: Disclosed are a backlight detection device and a backlight detection method. The device comprises a pixel value acquiring unit used to acquire a pixel value of each of pixels in an image; a focal position determination unit used to determine a focal position in the image; a subject area determination unit used to determine, based on the pixel values of the pixels in the image, a subject area starting from the focal position by using an area growth processing so as to divide the image into the subject area and a background area; a brightness difference calculation unit used to calculate a brightness difference between the subject area and the background area; and a backlight determination unit used to determine, based on the brightness difference, whether the image is in the backlight state so that the image in the backlight state can be detected.

Abstract: An image processing method and a device thereof are disclosed. In an image signal processor of the present invention, a process clock rate or an output clock rate for a preview mode is applied differently from a process clock rate or an output clock rate for a capture mode. When performing the capture mode, however, the process clock rate can be controlled to be the same as or larger than the output clock rate. With the present invention, the lagging can be reduced during the image processing.

Abstract: An image processing device and an image processing method determine whether the photographic scene has a high luminance difference. If the photographic scene has a high luminance difference, the image processing device and method switch the image pickup unit to a high luminance difference exposure mode. If the photographic scene does not have a high luminance difference, the image processing device and method switch the image pickup unit to a normal exposure mode.

Abstract: A digital camera includes: an image capture data creation unit; a CPU for directing the image capture data creation unit to perform image captures several times and acquire a plurality of image capture data; and an image processing device that determines whether or not a common specific image region exists in a plurality of image capture data acquired by the CPU and, in the case where it is determined that a specific image region exists, performs a pixel additive synthesis for image data of the specific image region and creates image data.

Abstract: An image capturing device includes an image sensing unit for sensing an image of a human face, an image processing unit, and a memory device. The image processing unit includes a face detection module, a brightness obtaining module, a comparing module, and an adjustment module. The face detection module is configured for detecting human faces in images sensed by the image sensing unit. The brightness obtaining module is configured for obtaining the brightness of a set of areas in the image corresponding to a set of preset portions of each human face. The comparing module is configured for comparing brightness of each of the areas to a threshold value. The adjustment module is configured for adjusting the image by decreasing the brightness of the areas whose brightness is greater than the threshold value. The memory device is able to store the images adjusted by the image processing unit.

Abstract: A method and apparatus for applying tonal correction to images to obtain a more pleasing photographic image by redistributing low-key, mid-tone and high-key tones. Luminance is calculated by using formulas appropriate for the color space or directly inputted. Two color-difference components are computed for the original image. Luminance is subjected to a tonal correction function to obtain a tonal corrected luminance. Luminance gain is calculated and applied to the color-difference components to obtain two tonal corrected color-difference components. The tonal corrected luminance and two tonal corrected color-difference components can be directly output or used to calculate three color component signals for the desired color space.

Abstract: The multi-band image photographing method and apparatus photograph a subject by dividing a photographing wavelength region into plural bands and obtain spectral images of the subject corresponding to the respective divided plural bands. The method and apparatus detect a sensitivity balance among the respective plural bands from photographing data of each of the spectral images obtained by preliminary photographing performed prior to main photographing, determine photographing conditions for the respective plural bands based upon the detected sensitivity balance, and perform the main photographing in accordance with the determined photographing conditions to photograph a multi-band image. The program is used to cause a computer to execute this method or part thereof.

Abstract: An image processor inputs image data from an image capturing device, and acquires blur-correction coefficients corresponding to the state of an imaging optical system which forms an image represented by light coming from an object on the image capturing device. Then, the image processor generates a target component and non-target components of blur correction from the image data, applies blur correction to the target component based on the blur-correction coefficients, and generates image data by synthesizing the target component after the blur correction and the non-target components.

Abstract: When an area desired to be displayed with high accuracy and an area desired to be inspected and measured with high accuracy in a measuring object are smaller than a photographing range, the entire area of a composite image is displayed and designation of an area is received, to thereby generate an image of the entire area in which composition processing of optimizing luminance of pixels included in this area is performed. Therefore, an input part is provided for receiving the setting of a designated area in image data, a composite luminance distribution is calculated based on the size of a standardized luminance distribution value in the designated area, and composite image data is generated.

Abstract: The application provides techniques for obtaining a relatively high dynamic range image of a scene using a relatively low dynamic range image sensor exposed to incident light from the scene for capturing an image. The image sensor has a multiplicity of light-sensing elements in an array and each light sensing element has a particular one of a plurality of sensitivity levels to incident light in accordance with a predetermined sensitivity pattern for the array of light-sensing elements and has a response function. Each light sensing element is responsive to incident light from the scene for producing a captured image brightness value at a corresponding one of a multiplicity of pixel positions of a pixel position array. Each one of the multiplicity of pixel positions corresponds to a particular one of the plurality of sensitivity levels of the light sensing elements.

Abstract: An apparatus and a method of smoothing the brightness of an image photographed in an image sensor without amplifying a noise component of a surrounding part of the image are disclosed.

Abstract: An image processing device for detecting a skin region representing a skin of a subject from a pickup image obtained by imaging said subject, the image processing device includes: a first irradiating section; a second irradiating section; an image pickup section; an adjusting section; and a skin detecting section.

Abstract: A photographing method and apparatus are provided. In the method, an image signal of an object region is detected from an input image signal, a shadow region is detected from the object region image signal, and an image signal obtained by superimposing the shadow region on the object region image signal is displayed. When removal of a shadow is requested after the input image signal is captured, the photographing method corrects a brightness level of the shadow region. The photographing apparatus includes an object region detecting unit configured to detect an image signal of an object region from an image signal; a shadow region detecting unit configured to detect a shadow region from the object region image signal, and an image signal superimposing unit configured to output an image signal detected by superimposing the shadow region detected by the shadow region detecting unit onto the object region image signal detected by the object region detecting unit.

Abstract: A method and apparatus for applying tonal correction to images to obtain a more pleasing photographic image by redistributing low-key, mid-tone and high-key tones. Luminance is calculated by using formulas appropriate for the color space or directly inputted. Two color-difference components are computed for the original image. Luminance is subjected to a tonal correction function to obtain a tonal corrected luminance. Luminance gain is calculated and applied to the color-difference components to obtain two tonal corrected color-difference components. The tonal corrected luminance and two tonal corrected color-difference components can be directly output or used to calculate three color component signals for the desired color space.

Abstract: An image processing apparatus (30) generating an image with high resolution over a diffraction limit includes an image input unit (101) receiving red image data and green image data, which represent images of an object by red light and green light, respectively, and receiving a blue image data representing an image of the object by blue light having a wavelength shorter than the red and the green light. Further, the image processing apparatus (30) includes an image processing unit (103) correcting the red and the green image data by adding thereon a spatial high frequency component contained in the blue image data, such that the image input unit (101) receives, as the blue image data, image data generated by light receiving elements provided at intervals shorter than a size of a smallest area that the red and the green light can converge.

Abstract: Luma adaptation for digital image processing. Luminance signals are separated from sensor RGB signals representing an image. A transfer function is obtained from the luminance signals. Using the transfer function, the sensor RGB signals are adjusted to adapt the luma of the image.

Abstract: In a system for converting an input image signal input from an image input device into an output image signal to be output by an image output device, an image compression unit converts a spectral image input via an image input unit into R, G, and B data, obtains principal component data by making principal component analysis of the spectral image, and stores these data in an input image storage unit. When the principal component data and R, G, and B data are loaded and stored in an output image storage unit, a spectral reflectance reconstruction unit reconstructs the spectral reflectance of each pixel using these data. A printer model determines the dot quantities of inks used to record each pixel in an image output device on the basis of the calculated spectral reflectance, and generates an output image signal for the image output device. In this way, image data which allows to estimate the spectral reflectance characteristics of an input image is provided, and faithful color reproduction can be realized.

Abstract: A flash device includes a stationary frame, a light emitting portion, a driving unit and a resilient plate. The light emitting portion is moveably received in the stationary frame and is spaced from the stationary frame. The driving unit includes a first magnetic assembly and a second magnetic assembly. The first magnetic assembly is positioned on the stationary frame. The second magnetic assembly is positioned on the light emitting portion and faces the first magnetic assembly. The driving unit is configured for driving the light emitting portion to move relative to the stationary frame through magnetical interaction between the first magnetic assembly and the second magnetic assembly. The resilient plate interconnects the stationary frame and the light emitting portion. The resilient plate is configured for moving the light emitting portion relative to the stationary frame.

Abstract: An interactive input system includes at least one illumination source emitting radiation into a region of interest; at least one imaging assembly capturing image frames of the region of interest, the at least one illumination source being in the field of view of the at least one imaging assembly; and a controller communicating with the at least one illumination source, the controller controlling the intensity of radiation emitted by the at least one illumination source during image frame capture.

Abstract: The present invention switches to and from generation of a luminance signal based on a visible light pixel signal and generation of a luminance signal based on a near infrared light pixel signal depending on a result of comparison of signal levels of the visible light pixel signal and the near infrared light pixel signal.

Abstract: An image processing apparatus includes an input section, an adjusting section, and a correcting section. The input section acquires image data and information about subject condition at the time of photographing the image data. The adjusting section determines a brightness enhancement amount of dark area gradation of the image data, depending on the subject condition at the time of photographing. The correcting section performs image correction of brightness enhancement on the dark area gradation of the image data according to the brightness enhancement amount determined by the adjusting section.

Abstract: On embodiment of the present invention sets forth a technique for automatically computing exposure parameters for a digital video camera (DVC) system. The exposure parameters include exposure gain, analog gain, and digital gain. Each frame is analyzed with respect to an image luma value. Exposure gain and analog gain are adjusted to reduce differences between a target image luma value and measured image luma values over sequential frames. Digital gain is adjusted with respect to each frame to reduce visually abrupt changes in sequentially captured video frames.

Abstract: An image apparatus (10) for providing an estimated final illuminant of a scene (12) and subsequently providing an adjusted image (218) of a scene (12) includes a capturing system (226) and a control system (232). The capturing system (226) captures information for an input image (416) of the scene (12) while at an apparatus setting. The input image (416) is defined by a plurality of input colors. The control system (226) can compare at least one of the input colors to an illuminant database (245) that includes an illuminant gamut of observable colors for a plurality of possible illuminants, and can evaluate the apparatus setting to select one of the possible illuminants to be the estimated final illuminant. Examples of possible apparatus settings include an aperture size and an exposure time. With this design, the present invention is better able to distinguish between some possible outdoor illuminants and some possible indoor illuminants with improved accuracy.

Abstract: An imaging apparatus includes a histogram shape determination unit that acquires a histogram of luminance values from video captured by an image capturing unit and determines whether or not the captured video is a night scene from the shape of the histogram. The imaging apparatus also includes a point light source determination unit that acquires the maximum value of contrast for each horizontal line in the video as a line evaluation value and determines whether the captured video is a night scene based on whether or not the line evaluation value has a characteristic of an object as a point light source. If the histogram shape determination unit and the point light source determination unit determine that the captured video is a night scene, the imaging apparatus determines that the scene captured by the image capturing unit is a night scene.