Abstract: A lens shading correction circuit includes a gain generator configured to generate a first gain value for each pixel of an input image in response to a gain generation parameter, and an adjustment circuit configured to receive the first gain value and first YUV data, and to adjust at least one of U and V values of the first YUV data using at least one of the first gain value and a Y value of the first YUV data.

Abstract: A solid-state imaging device includes a first detection pixel and a second detection pixel, each of the first detection pixel and the second detection pixel including a transfer transistor and an amplifier transistor connected to the transfer transistor via a first node, a voltage supply unit that supplies a predetermined voltage, and a connection switch connected between the voltage supply unit and a second node at which the transfer transistor of the first detection pixel and the transfer transistor of the second detection pixel are connected.

Abstract: An image pickup apparatus includes a specifying unit that specifies, as a transfer target, an image to be transferred to an external device from among images recorded in a recording medium, a transfer control unit that controls the specified image to be transferred to the external device, a display control unit that displays a predetermined screen for inputting an instruction for restricting deletion of the image specified as the transfer target, and a restriction unit that associates, in a case where the instruction for restricting the deletion of the image specified as the transfer target is input via the predetermined screen, information for restricting deletion with the image specified as the transfer target after inputting the instruction, and associates the information for restricting the deletion with images previously specified as the transfer target before inputting the instruction.

Abstract: An image adjustment apparatus includes a boundary calculation unit that calculates a boundary between a follow light region and a back light region in an image based on a position of a light source and an image adjustment unit that adjusts a state of the follow light region or the back light region with the boundary being a reference.

Abstract: First and second readout circuits, each having a respective floating diffusion node, are coupled to a photodetection element within a pixel of an integrated-circuit image sensor. Following an exposure interval in which photocharge is accumulated within the photodetection element, a first portion of the accumulated photocharge is transferred from the photodetection element to the first floating diffusion node to enable generation of a first output signal within the first readout circuit, and a second portion of the accumulated photocharge is transferred from the photodetection element to the second floating diffusion node to enable generation of a second output signal within the second readout circuit. A digital pixel value is generated based on the first and second output signals.

Abstract: In an image pickup apparatus, a parallax image acquisition unit acquires data of a plurality of viewpoint images having different viewpoints from an imaging unit. A detection unit detects the amount of change in a position or an attitude of the imaging unit which has generated the data of the plurality of viewpoint images. A calculation unit calculates a correction quantity of a shake correction unit and a mixture ratio of images when an image compositing unit generates a composite image from the plurality of viewpoint images on the basis of the amount of change in a position or an attitude of the image pickup apparatus. The image compositing unit generates a composite image from the plurality of viewpoint images using the calculated mixture ratio. The shake correction unit corrects image shake of the viewpoint images or the composite image according to the calculated correction quantity.

Abstract: A camera module includes a first position sensor configured to detect a position of a lens barrel in a first direction and including a 1-1-th sensing coil and a 1-2-th sensing coil having respective inductances that change as the lens barrel moves in the first direction; and a second position sensor including a second sensing coil having an inductance that changes as the lens barrel moves in a second direction, and a third sensing coil having an inductance that changes as the lens barrel moves in a third direction, wherein the second position sensor is configured to detect a position of the lens barrel in the second direction and a position of the lens barrel in the third direction by adding or subtracting a reference inductance to or from the inductance of the second sensing coil and the inductance of the third sensing coil.

Abstract: A lens shading correction circuit includes a gain generator configured to generate a first gain value for each pixel of an input image in response to a gain generation parameter, and an adjustment circuit configured to receive the first gain value and first YUV data, and to adjust at least one of U and V values of the first YUV data using at least one of the first gain value and a Y value of the first YUV data.

Abstract: A shooting device, comprising: an operation member for setting parameters, and a controller having a parameter preliminary setting section and a parameter calculation section for each condition, wherein the parameter preliminary setting section, before continuous shooting comprised of a series of a plurality of frames, performs preliminary parameter setting as a result of operation of the operation member for at least one point of shooting predetermined positions of the plurality of frames, and the parameter calculation section for each condition calculates parameter at the time of shooting the plurality of frames in accordance with the parameters that have been set in the parameter preliminary setting section.

Abstract: An array imaging module includes a molded photosensitive assembly which includes a supporting member, at least a circuit board, at least two photosensitive units coupled at the chip coupling area of the circuit board, at least two lead wires electrically connected the photosensitive units at the chip coupling area of the circuit board, and a mold sealer which includes a main mold body and has two optical windows. When the main mold body is formed, the lead wires, the circuit board and the photosensitive units are sealed and molded by the main mold body of the mold sealer, such that at least a portion of the circuit board are integrally formed together at a position that the photosensitive units are aligned with the optical windows respectively.

Abstract: Provided is a sound pick-up device which includes: a housing having a sound hole; a main microphone which is disposed in the inside of the housing, receives sound pressure from the outside of the housing through the sound hole, and generates a first sound signal; a reference microphone which is disposed in the inside of the housing and in a proximity of the main microphone and generates a second sound signal; a first shield which blocks between the inside of the housing and the inside of the main microphone; a second shield which blocks between the outside of the housing and the inside of the reference microphone; and a third shield which blocks between the inside of the housing and the inside of the reference microphone.

Abstract: An electronic device includes a housing having a first face that faces a first direction and a second face that faces a second direction which is opposite the first face, in which the first face is formed to have an at least partially transparent portion and at least one opening formed adjacent to the at least partially transparent portion; a camera located within the housing and including an image sensor that faces the first direction through the at least partially transparent portion in the housing; an acoustic component structure including a space that is at least partially formed between the camera and the second face of the housing and connected to the at least one opening, and at least one vibrating structure that is located in the space and is movable in the first direction or the second direction to generate sound; a circuit that is located within the housing and is electrically connected to the acoustic component structure to provide a sound-associated signal to the acoustic component structure; and

Abstract: To perform high-accurate correction while securing high-speed process, an image capturing apparatus comprises: an image capturing element having plural unit pixels; a first obtainer obtaining a pixel value of a first image generated by a first method, based on an output signal of the image capturing element; a second obtainer obtaining a pixel value of a second image for autofocus generated by a second method different from the first method, based on the output signal of the image capturing element; a first detector detecting a defective pixel based on the pixel value of the first image; a second detector detecting a defective pixel based on information of the defective pixel detected by the first detector and the pixel value of the second image; and a corrector correcting the second image, by correcting the pixel value of the second image corresponding to the defective pixel detected by the second detector.

Abstract: An electronic apparatus includes a touch detection unit that detects a touch operation on a touch panel, a selection unit that selects positions on a display unit via a touch operation on the touch panel, and a control unit that controls the selection unit, wherein, in a case where a touch position movement is performed on the touch panel, the control unit controls the selection unit to select, from among positions of a plurality of selective candidates on the display unit existing in a direction of the touch position movement from a starting position of the touch position movement to a touch position at a first timing, positions based on a touch position movement up to a second timing after the first timing.

Abstract: System and method for image turbulence correction includes: receiving a plurality of consecutive image frames; demosaicing previous, current and preceding image frames into a plurality of same size overlapping video tiles; determining a displacement of each of the video tiles; converting the video tiles of the current image frame, the previous image frame, and the plurality of preceding image frames into a frequency domain; iteratively processing the video tiles of the previous image frame, the current image frame and the plurality of preceding image frames for turbulence correction in the frequency domain; converting the turbulence corrected video tiles into a spatial domain, wherein the converted turbulence corrected video tiles form a single video frame tile including turbulence degradation correction; and mosaicing the single video frame tiles including turbulence degradation correction together to generate a full field of view turbulence correct video stream.

Abstract: An object of the invention is to provide an imaging system and an imaging control method that remove user discomfort in the display of an image associated with the adjustment of the direction of an optical axis of a pan tilt camera and improve visibility.

Abstract: Methods and apparatus provide for simulated, e.g., synthetic, aperture control. In some embodiments a user, after a camera autofocus or user selection of an object to focus on, sets a blur level and views the effect. Once the user controlled blur setting is complete, images are captured with the in-focus, e.g., autofocus, setting and other images are captured with the focus set to capture a blurred image based on the set blur level. In focus and out of focus images are captured in parallel using different camera modules in some embodiments. A composite image is generated by combining portions of one or more sharp and blurred images. Thus a user can capture portions of images with a desired level of blurriness without risking blurring other portions of an image while controlling how the captured images are combined to form a composite image with in-focus and blurred portions.

Abstract: Apparatus and methods are provided to create high dynamic range images by passing an incoming image through a color-neutral separation prism having at least three channels to produce a corresponding number of full color fractionated images, each channel aligned with a corresponding image capturing device for which an ISO sensitivity is selected to simultaneously achieve a different exposure value for each fractionated image and image capturing device, referred to as exposure bracketing, and recombining the simultaneously collected fractionated images to create a high dynamic range image. The apparatus and methods may be used for still photography or motion pictures.

Abstract: A large field-of-view (FOV) imaging apparatus includes a monocentric lens, and a plurality of imaging modules comprising digital mirror device(s) (DMD) arranged to form or arranged in proximity to a spherical focal surface in optical communication with the monocentric lens such that the monocentric lens directs light rays that enter the monocentric lens at a surface of the monocentric lens towards the spherical focal surface and into the imaging modules as a function of incident angle of each light ray relative to a reference plane.

Abstract: An image pickup apparatus capable of, when a photometry is performed using an output of an image sensor, performing the photometry without being affected by a diaphragm of an image pickup optical system is provided. A mode is switched between a display mode in which an image according to the image signal which is an output of the image sensor is displayed as a live image and a non-display mode in which the live image is not displayed. In the display mode, a lower limit value of an accumulation time during which an electric charge is accumulated in the image sensor at a time of photometry is controlled to a first lower limit value. In the non-display mode, the lower limit value of the accumulation time is controlled to a second lower limit value lower than the first lower limit value.