Abstract: An image signal processing apparatus includes an image signal input unit for inputting an image signal, a noise correcting unit for executing noise correction processing for the input image signal to output a noise-corrected image signal; an image signal correcting unit for executing signal level correction processing for the noise-corrected image signal to output a signal level-corrected image signal; an image signal correction intensity control unit for determining correction intensity of the signal level correction processing in the image signal correcting unit; a signal extension estimating unit for estimating a signal extension degree of signal extension based on the determined correction intensity; and a noise correction intensity control unit for calculating and controlling correction intensity of the noise correction processing in the noise correcting unit.

Abstract: An imaging apparatus has one of the interchangeable lens and the camera body acting as a master and the other acting as a slave. The master has a shake detection unit configured to detect a shake of the camera body and/or the interchangeable lens; and a shake correction processing unit configured to calculate an amount of shake correction for the correction lens and the imaging device based on an output from the shake detection unit. The shake correction processing unit performs arithmetic processing for calculating a shake correction signal and separates the shake correction signal into a low frequency domain and a high frequency domain. One of the lens driving unit and the device driving unit performs the image blur correction based on the shake correction signal of the high frequency domain, and the other performs the image blur correction based on the shake correction signal of the low frequency domain.

Abstract: A plurality of images of a scene may be obtained. These images may have been captured by an image sensor, and may include a first image and a second image. A particular gain may have been applied to the first image. An effective color temperature and a brightness of a first pixel in the first image may be determined, and a mapping between pixel characteristics and noise deviation of the image sensor may be selected. The pixel characteristics may include pixel brightness. The selected mapping may be used to map at least the brightness of the first pixel to a particular noise deviation. The brightness of the first pixel and the particular noise deviation may be compared to a brightness of a second pixel of the second image. The comparison may be used to determine whether to merge the first pixel and the second pixel.

Abstract: An image capturing apparatus includes a tilt detection unit that detects a tilt in the vertical direction, conversion data used for transforming plane coordinates into spherical coordinates, a correction unit that corrects the conversion data according to the tilt, a plurality of image capturing units, a coordinate transformation unit that transforms plane coordinates of a plurality of pixels included in images captured by the image capturing units into spherical coordinates according to the conversion data corrected by the correction unit, and a combining unit that combines the images including the pixels transformed into spherical coordinates by the coordinate transformation unit.

Abstract: Video image stabilization provides better performance on a generic platform for computing devices by evaluating available multimedia digital signal processing components, and selecting the available components to utilize according to a hierarchy structure for video stabilization performance for processing parts of the video stabilization. The video stabilization has improved motion vector estimation that employs refinement motion vector searching according to a pyramid block structure relationship starting from a downsampled resolution version of the video frames. The video stabilization also improves global motion transform estimation by performing a random sample consensus approach for processing the local motion vectors, and selection criteria for motion vector reliability. The video stabilization achieves the removal of hand shakiness smoothly by real-time one-pass or off-line two-pass temporal smoothing with error detection and correction.

Abstract: Provided are a ramp signal calibration apparatus and method and image sensor including the apparatus. The apparatus includes: an analog-to-digital converter (ADC) including a trimmable transistor having a gain value that varies according to stored data, and configured to receive a ramp signal in a state where the gain value is a first gain value, and to output first and second output signals; a subtractor configured to calculate a difference between the first and second output signals; a digital comparator configured to compare the difference with a reference value and to determine whether a slope of the ramp signal has changed; and a counter configured to change the stored data based on whether the slope of the ramp signal has changed, wherein when the counter changes the data, the first gain value of the trimmable transistor is changed to a second gain value according to the changed data.

Abstract: An optical apparatus includes an image sensor that includes a focus detecting pixel and an image pickup pixel, a first focus detector configured to provide a focus detection based upon a phase difference between the pair of image signals detected by the focus detecting pixel of the image sensor, a second focus detector configured to provide a focus detection based upon a contrast value based upon an output of the image pickup pixel of the image sensor, and a controller configured to provide autofocus utilizing the first focus detector when a focus detection precision of the first focus detector is equal to or higher than a first value and an image magnification variation amount calculated from a wobbling amount of the image pickup optical system used for the second focus detector is equal to or higher than a second value.

Abstract: At least one image processing apparatus is provided for preventing inadequate correction of, and to properly correct, a blur component in an image from occurring. The at least one image processing apparatus generates an image recovery filter for correcting chromatic aberration from an optical transmission function (OTF), and corrects the chromatic aberration of a captured image using the image recovery filter. Further, the at least one image processing apparatus calculates characteristics of a color blur of each area in a case where the image recovery filter has been used. Furthermore, the at least one image processing apparatus detects the remaining color blur in an edge of the image on which the chromatic aberration has been corrected using the image recovery filter from a result of calculating the characteristics of the color blur, and removes the color blur.

Abstract: An imaging apparatus includes an image sensor, an AD conversion unit, a clamp processing unit, and a video signal correction unit. The clamp processing unit is configured to clamp to a black level, an image signal of an effective pixel region or an optical-black region of the image sensor after having been digitally converted by the AD conversion unit, by evaluating a difference from a signal of the optical-black region. The video signal correction unit is configured to calculate signal information of a part or whole of the optical-black region of an image signal of the image sensor; and, independently for each color of the video signal, to calculate correction amount of a video signal using the signal information, and to carry out correction by subtracting calculated correction amount from the image signal before clamping operation performed by the clamp processing unit.

Abstract: An object is to provide a lens device that can share a cable and can prevent the unnecessary exposure of the cable, and an imaging apparatus that includes the lens device. A lens device according to an embodiment of the invention, which is replaceably mounted on an imaging apparatus main body, includes a lens barrel, a control unit that is provided on the lens barrel so as to protrude, a cable of which one end is connected to the control unit and the other end is connected to the imaging apparatus main body, a plurality of length regulating members that are provided in a longitudinal direction of the cable, and a housing portion in which the cable is housed and which is provided with an opening through which the cable is led out.

Abstract: A dark exposure control device comprises a dark exposure performing processor, an aperture-stop, and an aperture-stop driving processor. The dark exposure performing processor detects an image signal generated by an imaging device while the shutter is closed. The aperture-stop adjusts the amount of light incident on the imaging device. The aperture-stop driving processor adjusts the opening degree of the aperture-stop to smaller than the opening degree set for a main exposure while the dark exposure performing processor is operated.

Abstract: Provided is an image pickup apparatus, including: a lens portion including a focus lens unit and a magnification-varying lens unit; an image pickup element movable in an optical axis direction; a moving unit for moving the image pickup element in the optical axis direction; a memory unit for storing, as a reference position, a position of the image pickup element serving as a reference in the optical axis direction, the position corresponding to a zoom position; an operation unit for operating a defocus amount; and a controller for controlling the moving unit to move the image pickup element based on the reference position and the defocus amount operated by the operation unit.

Abstract: A CMOS imager assembly may include an integrated circuit (IC) having an active-pixel image sensor that is mounted on a printed circuit board (PCB) substrate using flip chip packaging technology. The IC and the PCB may be physically and electrically connected to each other through multiple electrically conductive connectors. An underfill material (which may include an anti-reflective material) may, during assembly, be introduced around the connectors in the space between the IC and the PCB. A chemical or physical discontinuity on the integrated circuit may, during assembly, prevent the underfill material from entering an area framed by the discontinuity, which may include the pixel array of the image sensor. The discontinuity may include a dam-like structure built up on the IC, a trench-like structure created on the IC, or a low surface tension material that has been applied to the surface of the IC.

Abstract: Method and device are described for customizing the content selection to present on a display device based on identifying the viewer of the device. In one embodiment, the present disclosure relates to selecting from among a group of digital images, those images that are most likely to be of interest to the viewer. In general, many of the images available to the display device will be comprised of images containing subject faces. Using the relationship information to predict subject affinity, the display device computes an image affinity for each image by accumulating the individual subject affinity predictions between the viewer and each subject identified in each image. The image affinities are used to select images for presentation on the display device.

Abstract: An image capturing apparatus includes an image capturing unit configured to change, between lines, a timing to receive light of an object image formed by an imaging optical system and accumulate charges, a storage unit configured to store a captured image, a shake detection unit configured to detect a shake, an image stabilization unit configured to optically correct an image blur caused by the shake, a distortion correction amount calculation unit configured to calculate, based on the output of the shake detection unit, a distortion correction amount used to correct a distortion caused in the image by the shake during charge accumulation of the image capturing unit, and a correction unit configured to correct the image stored in the storage unit based on the distortion correction amount.

Abstract: A focus detecting apparatus includes: a lens; a light-transmitting unit; a light-receiving unit; and an optical film that transmits a beam of light passing through the lens and includes a holographic optical element, a diffractive optical element, or a pellicle mirror, wherein a beam of light from the light-transmitting unit is reflected on a reflection mirror including the optical film, passes through a first exit pupil area on one side of an optical axis, and is transmitted to the subject, a beam of reflected light of light irradiated onto the subject passes through a second exit pupil area on another side of the optical axis, is reflected on the reflection mirror and received by the light-receiving unit, and a focal position is obtained using position information of the beam of light received by the light-receiving unit. Autofocusing can be continuously performed during continuous photographing operation and in low brightness environment.

Abstract: A method for conditioning a network based encoded video stream including receiving the video stream over an RF data link, detecting any missing and/or corrupted data within the data stream, and inserting curative data in place of the missing or corrupted data. A system and method for transmitting a real-time video stream to an end-user at least partially over an RF data link including the video conditioner wherein a camera obtains video footage, an encoder to compresses the video stream, an RF transmitter transmits the encoded video stream over an RF data link, and an RF receiver to receives the encoded video stream from the RF transmitter. The video stream is conditioned by the video conditioner and routed to an end user through a computer network wherein a decoder decodes the encoded video stream and the video stream is viewed on a display.

Abstract: A multi-spectral camera comprises a blocking element (201) having at least one hole (203) allowing light to pass through. A dispersive element (205) spreads light from the at least one hole (203) in different wavelength dependent directions and a lens (207) focuses light from the dispersive element (205) on an image plane (209). A microlens array (211) receives light from the lens (207) and an image sensor (213) receives the light from the microlens array (211) and generates a pixel value signal which comprises incident light values for the pixels of the image sensor (213). A processor then generates a multi-spectral image from the pixel value signal. The approach may allow a single instantaneous sensor measurement to provide a multi-spectral image comprising at least one spatial dimension and one spectral dimension. The multi-spectral image may be generated by post-processing of the sensor output and no physical filtering or moving parts are necessary.

Abstract: An optical device comprises an image blur compensation unit which compensates a blur in an image formed by an imaging optical system, the image blur compensation unit being movable in directions not parallel to an optical axis of the imaging optical system, a shake detection unit which detects shake of a device, a position detection unit which detects a position of the image blur compensation unit, the position detection unit having a detection accuracy that is variable, a driving control unit which calculates a driving target position of the image blur compensation unit based on an output from the shake detection unit and position information of the image blur compensation unit, and a control unit which controls detection accuracy of the position detection unit to set the detection accuracy of the position detection unit to a greater value in still image capture than a value in video capture.

Abstract: The present invention provides a digital camera which can overlay a plurality of images in multiple exposure shooting without intermingling with each other. A digital camera includes an image sensor constituted by a color filter for a plurality of color components, an imaging unit configured to capture a subject image with the image sensor and output the image data, a comparison unit configured to compare first image data output from the imaging unit with second image data output from the imaging unit between image data in corresponding regions within a screen, and a selecting unit to output either the first image data or the second image data for each region according to a comparison result.