Abstract: An apparatus comprising: means for processing, at a first time, a user-input to determine a position condition defined in respect of an object that is yet to be included in a sensed image; and means for automatically capturing, after the first time, a sensed image including a first object not included in the sensed image at the first time, in response to determination that the user-input position condition is satisfied in respect of the first object.

Abstract: A solid-state imaging device includes a photodetecting unit, a row control unit, a column control unit, and a signal readout unit. The photodetecting unit includes M×N pixel units P(1,1) to P(M,N) two-dimensionally arrayed in M rows and N columns. Each pixel unit P(m,n) includes a photodiode PD, an amplifying transistor Tr1, a transfer transistor Tr2, a readout transistor Tr3, a first initialization transistor Tr4, and a second initialization transistor Tr5. One of the transfer transistor Tr2 and the first initialization transistor Tr4 performs an on/off operation based on a control signal output from the row control unit, and the other performs an on/off operation based on a control signal output from the column control unit.

Abstract: A solid-state imaging device includes a plurality of pixels arrayed in a matrix, a plurality of first latch circuits, a first read bit line, a plurality of first driver circuits, a first amplifier, a second latch circuit, a second driver circuit, and a column scanning circuit. Each of the plurality of first latch circuits holds first pixel data which is obtained from a pixel located on the corresponding unit column. Each of the plurality of first driver circuits outputs the first pixel data, which is held in a corresponding one of the first latch circuits, to the first read bit line. The first amplifier amplifies a voltage of the first read bit line to generate first data. The second latch circuit holds the first data. The column scanning circuit sequentially outputs a plurality of the first pixel data by sequentially selecting the plurality of first driver circuits and selecting the second driver circuit.

Abstract: A method is disclosed for improving the quality of photographs taken in low-light conditions by adjustment of shutter speed and digital gain based on a shutter prioritization value. Using a network of sensor, a digital camera processes various parameters, such as luminance of the scene and movement of the camera or of subjects within the scene, to compute a shutter prioritization value. The value is then used to select the most appropriate shutter speed and digital gain combination from a constant exposure curve. Higher prioritization values correspond to faster shutter speeds and higher digital gain. Lower prioritization values correspond to lower shutter speeds and lower digital gain. In further embodiments, the shutter prioritization value may be manually customized by a user in order to produce artistic effects.

Abstract: The lens tube includes a cylindrical barrel, a holder, a cap, and a stress applying portion. The barrel houses at least one first lens. The holder houses an imaging element and is fixed to a substrate. The holder is configured to allow one end of the barrel in an axial direction to be screwed into the holder such that an optical axis of the first lens and an optical axis of the imaging element are aligned with each other. The cap is mountable to the barrel by allowing the other end of the barrel in the axial direction to be screwed into the cap. The stress applying portion is located between the holder and the cap when the barrel is screwed into the holder and the cap, and applies a stress in a direction in which the cap is separated from the holder. The first lens is held and fixed between a first stopper formed on the cap and a second stopper formed in the barrel when the cap is mounted to the barrel.

Abstract: The embodiment of the present invention discloses a shot image processing method comprising: obtaining composition target information in initial image data captured by a lens; obtaining a corresponding target composition area according to the composition target information; and obtaining the initial image data in the target composition area so as to obtain target image data. The embodiment of the present invention also discloses a shot image processing apparatus. By adopting the present invention, for the obtained initial image data captured by the lens, the composition target information in the initial image data can be automatically obtained, the corresponding target composition area can be obtained according to the composition target information, and then the initial image data in the target composition area can be obtained so as to obtain target image data, thereby improving the intelligence of the shooting terminal.

Abstract: Methods and electronic devices are provided that obtain a reference image of an imaged body using a first camera disposed on a first side of an electronic device, obtain image data of the imaged body using a second camera disposed on an opposite, second side of the electronic device, and provide guidance to an operator of the electronic device based on a comparison between the reference image and the image data. The guidance notifies the operator how to move the electronic device so that the imaged body in the image data is closer to being spatially aligned with a reference location of the imaged body in the reference image.

Abstract: System and method for improving the shaving experience by providing improved visibility of the skin shaving area. A digital camera is integrated with the electric shaver for close image capturing of shaving area, and displaying it on a display unit. The display unit can be integral part of the electric shaver casing, or housed in a separated device which receives the image via a communication channel. The communication channel can be wireless (using radio, audio or light) or wired, such as dedicated cabling or using powerline communication. A light source is used to better illuminate the shaving area. Video compression and digital image processing techniques are used for providing for improved shaving results. The wired communication medium can simultaneously be used also for carrying power from the electric shaver assembly to the display unit, or from the display unit to the electric shaver.

Abstract: A photographing apparatus is provided. The apparatus includes a first buffer configured to store a plurality of images generated by a first camera module among a plurality of camera modules, a second buffer configured to store a plurality of images generated by a second camera module among the plurality of camera modules, a display configured to display an image generated by the first camera module as a live image, and a controller configured to analyze the images stored in the first buffer and the second buffer using at least one of image information of each image stored in the first buffer and the second buffer and photographing information of the plurality of camera modules, and in response to an event occurring in at least one of the plurality of images stored in the second buffer, to control the display to provide a state notification service on the second camera module.

Abstract: Methods and apparatuses for irregular-region based automatic image correction are disclosed. In one aspect, the method is operable by an imaging device including a touch sensor, for performing image correction. The method can include obtaining a first image of a scene and receiving, via the touch sensor, a touch input indicating a selected region of the first image and having a shape that corresponds to a shape of the selected region. The method can also include determining statistics indicating visual properties for the selected region, adjusting at least one image correction parameter of the imaging device based on the determined statistics and the shape of the touch input, and obtaining a second image of the scene based on the adjusted at least one image correction parameter of the imaging device.

Abstract: An image-capturing device includes: a plurality of microlenses arranged in a two-dimensional manner; a plurality of photodetectors arranged to correspond to the plurality of microlenses; an image synthesizing part that synthesizes an image at an optional image plane of a photographic optical system, based on signals from the plurality of photodetectors; and an image processing part that removes signals of other pixels from signals of pixels constituting the image synthesized in the image synthesizing part.

Abstract: An image capture apparatus includes an image capture unit, a first correction unit configured to correct a black level of an image signal output from the image capture unit, a combining unit configured to select pixels to be used from among a plurality of image signals, the black level of which has been corrected by the first correction unit, to generate a combined image signal, and a second correction unit configured to correct the black level of the combined image signal generated by the combining unit.

Abstract: Imagers and associated devices and systems are disclosed herein. In one embodiment, an imager includes a pixel array and control circuitry operably coupled to the pixel array. The pixel array includes an imaging pixel configured to produce a reset signal and a non-imaging pixel configured to produce a nominal reset signal. The control circuitry is configured to produce an output signal based at least in part on one of (a) the nominal reset signal when distortion at the imaging pixel exceeds a threshold and (b) the reset signal when distortion does not exceed the threshold.

Abstract: A photoelectric conversion device includes a photoelectric converter, a transistor having a gate to which a voltage corresponding to charges generated by the photoelectric converter is supplied, a control line connected to a first main electrode of the transistor, and a readout unit configured to read out a signal corresponding to a voltage of the gate, and a voltage controller configured to change a voltage of the control line. The readout unit generates a digital signal corresponding to the voltage of the gate, based on a current flowing through a second main electrode of the transistor during a period in which the voltage controller changes the voltage of the control line.

Abstract: A solid-state imaging device is capable of simplifying the pixel structure to reduce the pixel size and capable of suppressing the variation in the characteristics between the pixels when a plurality of output systems is provided. A unit cell includes two pixels. Upper and lower photoelectric converters and, transfer transistors and connected to the upper and lower photoelectric converters, respectively, a reset transistor, and an amplifying transistor form the two pixels. A full-face signal line is connected to the respective drains of the reset transistor and the amplifying transistor. Controlling the full-face signal line, along with transfer signal lines and a reset signal line, to read out signals realizes the simplification of the wiring in the pixel, the reduction of the pixel size, and so on.

Abstract: A solid-state image sensor includes a plurality of pixels for focus detection, each of the pixels including a photoelectric converter arranged in a semiconductor substrate, a microlens, and a light blocking portion arranged between the semiconductor substrate and the microlens to cover part of the photoelectric converter. A face in the pixel, which is parallel to a surface of the semiconductor substrate and on which the light blocking portion is arranged, includes a first opening and a second opening in addition to the light blocking portion. The light blocking portion includes a separator that has a light blocking property and is arranged between the first opening and the second opening. The second opening is larger in area than the first opening, and the light blocking portion is larger in area than the first opening.

Abstract: A digital camera includes a body that contains a CCD image sensor for capturing an object image, a monitor that is pivotably mounted relative to the body and displays an image signal relating to the object image captured by the CCD image sensor, a microphone, and a controller for changing sound pickup directivity of the microphone according to an orientation of the monitor relative to the body. This increases sound pickup sensitivity for voice-enabled shutter operation.

Abstract: A MEMS auto focus miniature camera module includes an image sensor and an optical train including at least one movable lens and one or more fixed lenses or fixed lens groups on either side of the movable lens. The movable lens provides an auto focus feature of the camera module. A MEMS actuator translates the movable lens through an auto focus range to adjust focus.

Abstract: An image capturing module applicable to a portable electronic device is provided. The image capturing module includes an approximately cylindrical casing, an image capturing sensor, an accommodation space, and at least one magnet. The casing includes a first side having a projection, and a second side, opposed to the first side, having a charging contact. The image capturing sensor is disposed on an outer surface of the casing. The accommodation space is disposed in the casing for receiving a battery. The at least one magnet is disposed between the first side of the casing and the accommodation space.

Abstract: A solid-state imaging device includes a plurality of first photoelectric conversion elements, a plurality of second photoelectric conversion elements different from the plurality of first photoelectric conversion elements, a plurality of storage units, and a control unit. The plurality of storage units store signal charges output only from the plurality of first photoelectric conversion elements. The control unit controls operations of a first mode of outputting first signals based on signal charges output only from the plurality of first photoelectric conversion elements and stored in the plurality of storage units and a second mode of outputting second signals based on signal charges output from the plurality of first photoelectric conversion elements and the plurality of second photoelectric conversion elements without passing through the plurality of storage units.