Abstract: A focusing control device includes a phase difference calculation unit 11a which calculates the phase difference between a signal group output from a plurality of pixels 52A for phase difference detection and a signal group output from a plurality of pixels 52B for phase difference detection, a lens drive control unit 11c which drives a focus lens according to a drive amount corresponding to the phase difference, and a phase difference prediction unit 11b which calculates a predicted value of a phase difference at a time t(n+1) based on a coefficient a(n) for converting a phase difference calculated at a time t(n) to a drive amount and the difference ?m(n+1) between a movement amount of the focus lens from the time t(n) at the time t(n+1) after the focus lens starts to move according to the drive amount and the drive amount.

Abstract: A system and method for recording video that combines video capture, touch-screen and voice-control technologies into an integrated system that produces cleanly edited, short-duration, compliant video files that exactly capture a moment after it has actually occurred The present invention maintains the device in a ready state that is always ready to capture video up to N seconds or minutes in the past (where N depends on available system memory). This enables the user to run the system indefinitely without having to worry about running out of storage. Touch gestures and voice commands actually initiate captures without having to actually monitor the system itself thereby allowing for complete focus on the live action itself. When the user sees something happen, he or she can use an appropriate voice or touch command to cause the system to create a video media file based on time points derived from the user's commands.

Abstract: A device comprises a first digital camera having a first center line of sight and a second digital camera having a second center line of sight that is parallel and opposing the first camera. A method for controlling the first camera based on estimating the angular deviation between a person gaze direction and the line of sight of the first digital camera. A human face is detected in an image captured as an image file by the second digital camera, using a face detection algorithm. An angular deviation ? is estimated, defined between the second center line of sight and an imaginary line from the second camera to the detected human face based on the captured image, and an angular deviation ? is estimated, defined between the imaginary line from the second camera to the detected face and the human face gaze direction based on the captured image.

Abstract: Provided is a method for reproducing a situation using a mobile device having an image shooting function. The method may include extracting first keypoints from a live view output to a display of the mobile device, extracting second keypoints from a previously shot image, calculating a tilt of the mobile device at which the first keypoints are mapped to the second keypoints within a critical range, and synthesizing the previously shot image with the live view in a state where the mobile device has been adjusted according to guide information based on a result of the calculating.

Abstract: A wearable imaging apparatus is provided for capturing and processing images from an environment of a user. In one implementation, the wearable apparatus may be configured with a memory for storing privacy mode triggers and associated automatically variable privacy mode settings, and at least one processing device. The processing device may analyze the images captured by the wearable apparatus, and recognize the presence of at least one of the privacy mode triggers within the images. After recognizing the at least one trigger, the processing device may cause one or more adjustments to the wearable apparatus based on the privacy mode settings associated with the at least one trigger.

Abstract: A computerized method for computing the photo quality of a captured image in a device image acquisition system, comprising on-board combining of a plurality of quality indicators computed from said captured image and its previous image frames quality indicators and a confidence level for at least one of said quality indicators, and using a processor to determine, based on said combining, whether photo quality is acceptable and taking differential action depending on whether quality is or is not acceptable.

Abstract: An electronic device and a method of operating a panorama function in the electronic device are provided. The electronic device includes at least one processor, a memory, a camera configured to sequentially obtain a plurality of images if an image capture is started, and a sensor configured to sense motion of the electronic device. The at least one processor is configured to store in the memory a panorama content file comprising panorama image data and dynamic panorama data generated based on the plurality of images and the motion of the electronic device sensed during the image capture.

Abstract: An accessory apparatus attached to an interchangeable lens attached to a camera body can switch between a first accessory power mode and a second accessory power mode consuming less power than the first accessory power mode. The power state of the accessory apparatus is set based on information regarding the power mode of the camera body and the power mode of the interchangeable lens.

Abstract: A system and a method for stabilizing a data stream from an in-flight object may provide at least one video camera that may be embedded in the object. A data stream of the at least one video camera may be processed and produce an output video that may be stabilized and configured for broadcasting an action. The output video may provide an orientation that may provide an accurate view of the action. An object imaging system may be provided to receive the data stream from the at least one video camera, and a video processing server may be provided to process the data stream. The object imaging system may provide a wide angular field of view that may provide clear images for the output video.

Abstract: An image processing apparatus comprises the following units. A dividing unit divides a frame of a moving image into a changing area in which there is an active object and a changeless area in which there is a stationary object. A generation unit generates a still image by compositing an area corresponding to the changeless area in each of X frame(s) (where X is an integer of 1 or more) among a plurality of frames included in the moving image and an area corresponding to the changing area in each of Y frames (where Y is an integer greater than X) among the plurality of frames.

Abstract: Techniques to capture and fuse short- and long-exposure images of a scene from a stabilized image capture device are disclosed. More particularly, the disclosed techniques use not only individual pixel differences between co-captured short- and long-exposure images, but also the spatial structure of occluded regions in the long-exposure images (e.g., areas of the long-exposure image(s) exhibiting blur due to scene object motion). A novel device used to represent this feature of the long-exposure image is a “spatial difference map.” Spatial difference maps may be used to identify pixels in the short-and long-exposure images for fusion and, in one embodiment, may be used to identify pixels from the short-exposure image(s) to filter post-fusion so as to reduce visual discontinuities in the output image.

Abstract: An imaging apparatus includes: a first display panel unit for executing display toward a user side; a second display panel unit for executing display toward a subject side; an imaging processing unit for subjecting incident light from the subject side to photoelectric conversion to obtain a captured image signal; a recording processing unit for executing a recording process to a recording medium regarding the captured image signal obtained at the imaging processing unit; and a control unit for controlling the display states of the first display panel unit and the second display panel unit for each of a plurality of various types of operation periods changing along with the operation of the imaging processing unit or the recording processing unit, and executing display control wherein the first display panel unit and the second display panel unit can have different display content during at least a single operation period.

Abstract: A conversion method for converting luminance of a video, including a luminance value in a first luminance range, to be displayed on a display apparatus includes: acquiring a first luminance signal indicating a code value obtained by quantization of the luminance value of the video; and converting the code value indicated by the acquired first luminance signal into a second luminance value determined based on a luminance range of the display apparatus, the second luminance value being compatible with a second luminance range with a maximum value smaller than a maximum value of the first luminance range and larger than 100 nit. This provides the conversion method capable of achieving further improvement.

Abstract: The present invention relates to an image capture apparatus includes a substantially spherical housing and two cameras. The apparatus resembles a billiard ball by and large, and could roll or rotate to an extent with the spherical housing. Meanwhile the housing has a small flat bottom, so that the image capture apparatus can stand still with the flat bottom on a plane surface. The two cameras are positioned above the flat bottom and substantially opposite to each other in the housing and point substantially horizontally with the flat bottom.

Abstract: A subject detecting unit 107 calculates a subject position on the basis of a subject region obtained by calculating the difference between an overhead image generated from an image for difference calculation stored in an image for difference calculation storage unit 106 and an overhead image generated by an overhead image generating unit 105. A projection plane calculating unit 108 forms a projection plane at the subject position, and a subject image generating unit 109 projects camera images of image taking devices 1a to 1c onto the projection plane, and generates a subject image. A display image generating unit 110 outputs to a display 2 an image formed by synthesizing the subject image with the overhead images generated by the overhead image generating unit 105.

Abstract: A sample key signal frame (602) and/or a sample image frame (601) may be stored showing a finely detailed element (101) at a first resolution (e.g. a zoomed-in image). A current image signal (71) includes the same finely-detailed element (101) at a second, lower, resolution (e.g. a wide-angle image). The sample (601, 602) is scaled and/or transformed to match a target area (10,14) within the current image (71), and may be used to perform an image enhancement process which enhances the detailed element (101) within an enhanced modified image frame (74). Thus, a more photo-realistic image is achieved.

Abstract: The present invention relates to an image sensor sensor having improved spectral characteristics, and improves a color characteristic and sensitivity of an image sensor by implementing an image sensor sensor using a stacked substrate structure having photodiodes formed on each of two substrates, and generating a color signal having improved spectral characteristics based on an electrical signal outputted from each of the photodiodes formed on two substrates.

Abstract: Provided is an imaging device including row drive unit having a first storage unit that stores and outputs a first signal for a readout from the pixels on an associated row, a second storage unit that stores and outputs a second signal for an operation for causing the photoelectric conversion element on an associated row to be reset to a charge accumulation state, and a third storage unit that stores and outputs a third signal for maintaining the photoelectric conversion element on an associated row in a charge accumulation state or a reset state based on the first signal output from the first storage unit and the second signal output from the second storage unit.

Abstract: The invention is relates to systems and methods for high dynamic range (HDR) image capture and video processing in mobile devices. Aspects of the invention include a mobile device, such as a smartphone or digital mobile camera, including at least two image sensors fixed in a co-planar arrangement to a substrate and an optical splitting system configured to reflect at least about 90% of incident light received through an aperture of the mobile device onto the co-planar image sensors, to thereby capture a HDR image. In some embodiments, greater than about 95% of the incident light received through the aperture of the device is reflected onto the image sensors.

Abstract: A read-out circuit of an image sensor includes a ramp signal generator, a bias voltage generator and a conversion circuit. The ramp signal generates a ramp signal that linearly varies at a constant slope. The bias voltage generator generates a bias voltage based on a power supply voltage having a first noise component. The conversion circuit generates a reference voltage based on the bias voltage and the ramp signal, and performs an analog-to-digital conversion on an analog signal from a pixel to generate a digital signal corresponding to the analog signal. The analog signal has second noise component. The bias voltage generator adjusts an alternating current component included in the bias voltage such that a magnitude of a third noise component added to the reference voltage is substantially the same as a magnitude of the second noise component.

Abstract: A photoelectric conversion device includes a pixel array including pixels arranged in rows and columns, each of the pixels being configured to output a pixel signal, and including an optical filter and a photoelectric conversion unit, wherein the optical filters of different colors are arranged for each rows and each columns, a holding circuit including first holding units for each of the columns, the first holding units being configured to respectively hold the pixel signals read out from the pixels including the optical filters of different colors in one column of the pixel array in parallel, an output signal line, and a readout circuit configured to successively read out the pixel signals of pixels including the optical filters of the same color from the first holding units for each of the columns to the output signal line.

Abstract: A solid-state imaging device is provided, which includes a photodiode having a first conductivity type semiconductor area that is dividedly formed for each pixel; a first conductivity type transfer gate electrode formed on the semiconductor substrate via a gate insulating layer in an area neighboring the photodiode, and transmitting signal charges generated and accumulated in the photodiode; a signal reading unit reading a voltage which corresponds to the signal charge or the signal charge; and an inversion layer induction electrode formed on the semiconductor substrate via the gate insulating layer in an area covering a portion or the whole of the photodiode, and composed of a conductor or a semiconductor having a work function. An inversion layer is induced, which is formed by accumulating a second conductivity type carrier on a surface of the inversion layer induction electrode side of the semiconductor area through the inversion layer induction electrode.

Abstract: The present technology relates to signal processing device and method, an imaging element, and an electronic device capable of reducing a rise of costs. A signal processing device according to the present technology includes a measurement unit that performs measurement of a length of a period from an input start of a signal to a change of a value of the signal a plurality of times, retains measured values obtained by the measurement performed the plurality of times, sets an initial value of the measurement on the basis of any one of a plurality of the retained measured values, and performs the measurement by using the initial value. The present technology is applicable to an electronic circuit such as a flip-flop circuit and an A/D conversion unit, an imaging element such as a CMOS image sensor, and an electronic device such as a digital still camera, for example.

Abstract: A light field imaging system with transparent photodetectors is presented. The light field imaging system includes: a stack of two or more detector planes, an imaging optic, and an image processor. The detector planes include one or more transparent photodetectors, such that transparent photodetectors have transparency greater than fifty percent (at one or more wavelengths) while simultaneously exhibiting responsivity greater than one amp per watt. The imaging optic is configured to receive light rays from a scene and refract the light rays towards the stack of two or more detector planes, such that the refracted light rays pass through the transparent detector planes and the refracted light rays are focused within the stack of detector planes. The image processor reconstruct a light field for the scene (at one of more wavelengths) using the light intensity distribution measured by each of the photodetectors.

Abstract: A camera system includes an imager unit for recording image data and converting the image data into a digital image signal, and a video processing unit operatively connected to the imager unit for receiving the digital image signal from the imager unit and for generating a corrected video output signal. The video processing unit has a dead pixel correction unit and a subsequent non-uniform offset error correction unit. The dead pixel correction unit is configured for correcting the signal of confirmed dead pixels, which are referenced in a map of confirmed dead pixels associated to the dead pixel correction unit. The non-uniform offset error correction unit is configured for correcting readout amplifier non-uniformity and pixel level non-uniformity in the digital image signal. The non-uniform offset error correction unit is further configured for new dead pixel detection simultaneously to the pixel level non-uniformity correction.

Abstract: A solid-state imaging device includes a pixel array unit in which a plurality of imaging pixels configured to generate an image, and a plurality of phase difference detection pixels configured to perform phase difference detection are arranged, each of the plurality of phase difference detection pixels including a plurality of photoelectric conversion units, a plurality of floating diffusions configured to convert charges stored in the plurality of photoelectric conversion units into voltage, and a plurality of amplification transistors configured to amplify the converted voltage in the plurality of floating diffusions.

Abstract: The present technology relates to a solid-state imaging element, a driving method therefor, and an electronic apparatus, by which the characteristics of phase-difference pixels can be made constant irrespective of a chip position. In a pixel array section, a normal pixel including a photodiode (PD) that receives and photoelectrically converts incident light such that a color component signal is obtained, and a phase-difference pixel including a pair of a photodiode (PD1) and a photodiode (PD2) including light-receiving surfaces having a size depending on an image height such that a phase difference detection signal is obtained are arranged in a matrix form. The pair of the photodiode (PD1) and the photodiode (PD2) each include a first region serving as a charge accumulation main part and a second region that performs photoelectric conversion and contributes to charge transfer to the main part. The present technology is applicable to a CMOS image sensor, for example.

Abstract: A method of driving a unit pixel may include activating a transfer signal prior to an activation of a reset signal to boost a floating diffusion node of the unit pixel, during a first section of a photodiode reset period; and activating a reset signal using a hard reset, during a second section of the photodiode reset period.

Abstract: A double-sided image sensor can capture images from two different perspectives during two different time intervals. For example, during a first time period, the image sensor captures the view relative to a first side of an electronic device containing the image sensor, but during a second time period, captures the view relative to a second side of the electronic device. To capture images from multiple views, the double-sided image sensor contains a layer of photodiodes which captures measurements from multiple directions. Moreover, the image sensor includes selectable attenuators (e.g., mechanical shutters or TN attenuators) which control what view the photodiodes are currently capturing. For example, when capturing an image from the backside of the electronic device, one of the selectable attenuators blocks light from striking the photodiodes from the front side, and as such, only the light entering at the backside strikes the photodiodes.

Abstract: The present technology relates to a signal processing device, an image pickup element, and an electronic device capable of suppressing power source variation due to driving of a counter. The signal processing device according to the present technology includes a first A/D converter which performs A/D conversion on an analog signal by using a first counter being a predetermined counter and a second A/D converter which performs the A/D conversion on the analog signal by using a second counter count timing of which is the same as that of the first counter and a polarity of a count value of which is opposite to that of the first counter. The first and second A/D converters are arranged in the vicinity of each other such that power source variations thereof affect both. The present technology may be applied to the image pickup element and the electronic device, for example.

Abstract: An image sensor comprises: a plurality of pixels; a first reference signal generator configured to output a first reference signal whose signal level changes with time; a second reference signal generator configured to output a second reference signal whose signal level changes with time, a rate of change of the signal level of the second reference signal being larger than that of the first reference signal; an analog-to-digital converter configured to perform an analog-digital conversion of a pixel signal output from each of the plurality of pixels using the first reference signal or the second reference signal selected in accordance with a magnitude of the pixel signal, wherein the plurality of pixels and the first reference signal generator are arranged in a first chip, and the second reference signal generator is arranged in a second chip.

Abstract: An optical detector (110) is disclosed.

Abstract: An imaging device includes a plurality of pixels, each of which including a first pixel element including a first photoelectric conversion unit, and a second pixel element including a second photoelectric conversion unit lower in sensitivity than the first photoelectric conversion unit, a readout circuit configured to read out a first image signal based on signal charge generated in the first pixel element during a first accumulation period, and a second image signal based on signal charge generated in the second pixel element during a second accumulation period longer than the first accumulation period, the second image signal being synchronized with the first image signal, and a control unit configured to control the readout circuit so that a first readout period for reading out the first image signal is performed during the second accumulation period.

Abstract: A latch unit that starts an operation of capturing a data signal according to a startup instruction signal and holds the data signal and ends the capturing operation at a timing at which an execution instruction signal is input, a first signal path that transfers a latch timing signal as the startup instruction signal, and a second signal path that transfers the latch timing signal as the execution instruction signal are included, and a first logic element that outputs a first output signal switched to a logical value according to a logical value of an input signal at a first predetermined timing, and a signal maintenance logic circuit that continues to output a second output signal with a predetermined logical value according to the logical value of the input signal until initialization of a reset signal is indicated are arranged in the second signal path.

Abstract: A remote controller for providing a force input in a media system and a method for operating the same are disclosed. The remote controller comprises: at least one of a navigation key, a determination key or a function key, a first sensing unit configured to sense a coordinate of the key, a second sensing unit configured to sense one or more of pressure and an area applied to the key by a means for selecting the key, and a control signal unit. Here, one or more sensing levels are set to the key. The control signal unit outputs a control signal including a control information concerning the determined sensing level, the control information includes the coordinate of the selected key and information concerning the pressure or the area applied when the key is selected, and plural sensing levels from the same key are matched with different function or screen.

Abstract: A method of an electronic device for controlling sharing of video and an electronic device adapted to the method are provided. The electronic device includes a display, a communication circuit, a control circuit, and a memory electrically connected to the control circuit, where the memory stores instructions enabling the control circuit to control the communication circuit to transmit a first video to an external device connected to the electronic device, when a video sharing function is executed, display an icon on the display, when transmitting the first video, and control the communication circuit to pause the transmission of the first video and to transmit a second video to the external device, in response to a first input applied to the icon.

Abstract: A display device includes: a display unit configured to display an image of media content; an external device interface unit configured to receive an image signal outputted from an external device connected to the display device; and a control unit configured to control the display unit and the external device interface unit. The control unit displays a plurality of external input items, receives an instruction for positioning a pointer to one item among the plurality of external input items, displays a plurality of external input switching options on an external input item where the pointer is disposed according to the received instruction, and performs a function corresponding to a selected external input switching option among the plurality of external input switching options based on the image signal outputted from the external device.

Abstract: A display system includes a conversion apparatus converting video luminance including a luminance value in a first luminance range and a display apparatus connected thereto and displaying the video. The conversion apparatus includes a first acquisition unit, a first luminance converter, a second luminance converter, a quantization converter, and an output unit outputting a third luminance signal to the display apparatus.

Abstract: A display system includes a conversion apparatus converting video luminance including a luminance value in a first luminance range and a display apparatus connected thereto and displaying the video. The conversion apparatus includes a first acquisition unit, a first luminance converter, a second luminance converter, a quantization converter, and an output unit outputting a third luminance signal to the display apparatus.

Abstract: A display system includes a conversion apparatus converting video luminance including a luminance value in a first luminance range and a display apparatus connected thereto and displaying the video. The conversion apparatus includes a first acquisition unit, a first luminance converter, a second luminance converter, a quantization converter, and an output unit outputting a third luminance signal to the display apparatus.

Abstract: An image display device is a self-luminous type device including a light emitting portion, and a casing portion of a display device unit has a heat dissipating structure portion through which a part of the image display device is exposed for heat dissipation. In manufacturing the display device unit, when performing simple and reliable assembly while securing a high heat dissipation characteristic, for example, by using characteristics of a silicon substrate, high accurate positioning is performed in a display device positioning portion.

Abstract: There is provided an information processing apparatus, and a method to improve operability of the information processing apparatus when a user manages still image files in a case where a still image is extracted from a moving image file and stored as a still image file. In information processing apparatus and the method, a moving image file is selected from a plurality of moving image files and is reproduced, and a folder corresponding to the selected moving image file is created. A still image file is generated based on a video frame extracted from the moving image file being reproduced, and the generated still image file is stored into the created folder in association with the folder. When another moving image file is selected, another folder is newly created, and a still image file generated from the other moving image file being reproduced is stored into the other folder.

Abstract: In a video imaging apparatus, a camera module includes the imaging unit and an imaging control unit that controls the imaging operation of the imaging unit according to imaging control values, and the imaging apparatus main body connected to the camera module via a connection cable capable of bidirectional communication includes an image signal processing unit that outputs frame images of a video in sequence from the imaging signals and generates the imaging control values for controlling imaging operation of the imaging unit from the imaging signals. The imaging unit can determine whether the imaging control values input from the image signal processing unit via the connection cable are abnormal imaging control values under influence of noise.

Abstract: A first information terminal includes: a first imaging unit configured to capture a first video near a device to which the first information terminal is attached, and to generate first video data; a transmitting unit configured to transmit the first video data to a second information terminal that receives an operation for operating the device; a moving state determining unit configured to determine a moving state of the device, the moving state being made in response to the operation; and a video data transmission controller configured to control whether or not to transmit one of the first video data and the second video data from the transmitting unit depending on the moving state. The second video data is generated by a second imaging unit capturing a second video near the device. The second imaging unit is different from the first imaging unit.

Abstract: Decoding a current frame from an encoded video stream may include identifying a current transform block for decoding the current frame, the current transform block having a first transform block size, generating a reconstructed frame corresponding to the current frame, the current transform block corresponding to a first portion of the reconstructed frame, identifying a first boundary between the first portion and a second portion of the reconstructed frame, the second portion corresponding to a first adjacent transform block that is adjacent to the current transform block, the first adjacent transform block having a second transform block size, identifying first loop filter candidates based on the first transform block size, identifying a first loop filter from the first loop filter candidates based on the second transform block size, and filtering pixels from the reconstructed frame along the first boundary using the first loop filter.

Abstract: Implementations generally relate to virtual reality telepresence. In some implementations, a method includes positioning a first user in a virtual environment, and determining a first point of view associated with the first user. The method further includes positioning a second user in the virtual environment, and determining a second point of view associated with the second user. The method further includes projecting one or more of the first user and the second user in the virtual environment based on a first positioning of the first user and a second positioning of the second user and based on the first point of view and the second point of view.

Abstract: A method for videoconferencing includes steps of: receiving audio and video frames of multiple locations having at least one person at each location;—processing the video frames received from all the location except a base location, wherein processing the video frames to extract the person/s by removing background from the video frames of the location; merging the processed video frames with the base video to generate a merged video, so that the merged video give an impression of co-presence of the persons from all location at the location of the base video; and displaying the merged video.

Abstract: A monitoring system can detect and react to abnormal events in real-time is disclosed. The system includes: a receiver that receives the event related data from a plurality of sensors; a coverage analyzer that analyses predetermined data and the event related data from the receiver, the predetermined data including sensor coverage information; and a sensor selector coupled to the coverage analyzer that selects one or more of the plurality of sensors based on the analysis by the coverage analyzer.

Abstract: A remote follow spot system includes a remote controller that has separately movable parts that are movable in two orthogonal directions, and a display attached to one of said two separately movable parts. The display receives a video feed from a controlled light, that is controlled to move in the same directions as remote controller. The display hence shows the field of view where the light is pointing. In this way, an operator of the follow spot can control the light without physically being near the light.

Abstract: An electric vehicle charging station such as a smart Electric Vehicle Supply Equipment (EVSE) with an integrated camera is provided. A networked on-charging station camera unit disposed either internally to the smart EVSE or connected externally on the smart EVSE. The camera unit includes at least one of a video camera and a still image camera. A communication module is coupled to the camera unit to communicate acquired camera data over a camera connection to a server or to a mobile device of a user over one or more public networks, one or more private networks, or a combination of one or more public networks and one or more private networks.