Abstract: A super-resolution processing method of a moving image is provided. The super-resolution processing method of a moving image includes sequentially inputting a plurality of input frames included in the video to any one of a recurrent neural network (RNN) for super-resolution processing and a convolutional neural network (CNN) for super-resolution processing, sequentially inputting a frame sequentially output from the any one of the RNN and the CNN to an additional one of the RNN and the CNN, and upscaling a resolution of the output frame by carrying out deconvolution with respect to a frame sequentially output from the additional one of the RNN and the CNN.

Abstract: In one embodiment, a computing system receives one or more signals indicative of light intensities captured by one or more cameras. These signals are captured in a plurality of frames at a first frame rate. The computing system calculates light intensity metrics for each frame of the plurality of frames based on the one or more signals captured in the respective frames. The computing system detects one or more peaks based on the light intensity metrics associated with one or more frames of the plurality of frames. The one or more frames were captured in a predetermined time period. The computing system determines a likelihood of perceptible flicker based on the detected one or more peaks. The computing system causes the one or more cameras to capture frames at a second frame rate in response to a determination that the likelihood of perceptible flicker exceeds a predetermined threshold.

Abstract: An image capturing apparatus having a viewfinder, comprises a plurality of operating members to which functions are allowed to be assigned, a detecting unit configured to detect when an eye of a user is close to the viewfinder, and a control unit configured to, in a case where an operating member operated while the detecting unit detects that the eye is close is an operating member which is disposed in a prescribed location and a specific function is assigned to the operating member, forgo executing the function assigned to the operating member, and in other cases, execute the function assigned to the operating member.

Abstract: Provided are an imaging device capable of accelerating AF and a focusing control method thereof. A focus lens drive unit (16) that drives a focus lens (12), and an image sensor movement drive unit (120) that moves an image sensor (110) along an optical axis (L) are included. A target position of the focus lens (12) for focusing on a subject is set, and the focus lens (12) is moved toward the target position. The image sensor (110) is moved before the focus lens (12) reaches the target position such that focusing is performed. A focusing state is maintained by moving the image sensor (110) so as to follow the focus lens (12) after the focusing is performed.

Abstract: A computer system displays a representation of a field of view of one or more cameras that is updated with changes in the field of view. In response to a request to add an annotation, the representation of the field of view of the camera(s) is replaced with a still image of the field of view of the camera(s). An annotation is received on a portion of the still image that corresponds to a portion of a physical environment captured in the still image. The still image is replaced with the representation of the field of view of the camera(s). An indication of a current spatial relationship of the camera(s) relative to the portion of the physical environment is displayed or not displayed based on a determination of whether the portion of the physical environment captured in the still image is currently within the field of view of the camera(s).

Abstract: The present invention relates to a mobile terminal and a control method therefor and, more specifically, provides a mobile terminal comprising a camera, a sensing unit, a display unit, and a control unit, wherein the control unit outputs, on the display unit, a preview image captured through the camera in a state in which camera content is executed, the preview image includes at least one object, a control icon scrollable within a preset region is outputted on the display unit, the length of the control icon is a first length, and when the camera is focused on a first object included in the outputted preview image, at least one condition among size, outputted location, and speed of the first object is detected, and the length of the control icon is changed on the basis of the detected condition.

Abstract: An imaging device, a focusing control method, and a focusing control program are provided. The imaging device includes: an imaging element, having pixels including phase-difference detecting pixels and imaging a subject through an imaging optical system including a focus lens; and a focusing controller, selectively performing focusing control using a phase difference AF method or focusing control using a contrast AF method in a mode in which focusing control for focusing on a main subject by driving the focus lens is continuously performed multiple times. The focusing controller performs the focusing control using the contrast AF method in a case where a state in which a degree of reliability of the focusing control using the phase difference AF method is equal to or less than a threshold value persists N times (N=2 or more), while the focusing control using the phase difference AF method is continuously performed.

Abstract: An electronic device and a photographing control method thereof are provided. The electronic device includes: a housing; a camera provided in the housing; a display screen movably assembled to the housing, and switchable between a first state and a second state with respect to the housing. The display screen has a display portion and a non-display portion, and the non-display portion is light transparent. When the display screen is in the first state, the camera is covered by the display portion. When the display screen is in the second state, the camera faces to the non-display portion, and configured to collect light through the non-display portion and performs imaging.

Abstract: In an imaging apparatus, each of a plurality of pixels has a first semiconductor area having a first conductivity type, a floating diffusion area, and a transfer gate positioned between the first semiconductor area and the floating diffusion area. In a part of the plurality of pixels, a partial area of the first semiconductor area receives a potential supplied from a contact. The part of the plurality of pixels further has a second semiconductor area having a second conductivity type positioned between the partial area and the transfer gate in a planar view.

Abstract: Aspects of the present disclosure relate to systems and methods for determining a resampler for resampling or converting non-Bayer patter color filter array image data to Bayer pattern image data. An example device may include a camera having an image sensor with a non-Bayer pattern color filter array configured to capture non-Bayer pattern image data for an image. The example device also may include a memory and a processor coupled to the memory. The processor may be configured to receive the non-Bayer pattern image data from the image sensor, divide the non-Bayer pattern image data into portions, determine a sampling filter corresponding to the portions, and determine, based on the determined sampling filter, a resampler for converting non-Bayer pattern image data to Bayer-pattern image data.

Abstract: According to the disclosure, a relationship of Tgp>Tgf, ?f1<?PCB1, and (Tgp?To)×?PCB1<(Tgf?To)×?f1+(Tgp?Tgf)×?f2 or a relationship of Tgp<Tgf, ?PCB1<?f1, and (Tgf?To)×?f1<(Tgp?To)×?PCB1+(Tgf?Tgp)×?PCB2 is satisfied, where linear expansion coefficients in an in-plane direction of the substrate at a temperature below a glass transition temperature Tgp of the substrate and at a temperature above the glass transition temperature Tgp of the substrate are denoted as ?PCB1 and ?PCB2, respectively, linear expansion coefficient of the frame at a temperature below a glass transition temperature Tgf of the frame and at a temperature above the glass transition temperature Tgf of the frame are denoted as ?f1 and ?f2, respectively, and a room temperature is denoted as To.

Abstract: An imaging system includes an image sensing unit and a processing unit. The image sensing unit captures a plurality of images of an object, wherein each of the images includes a plurality of pixels. The processing unit obtains a plurality of sets of image data according to the images, wherein each set of image data includes a plurality of characteristic values. The processing unit calculates a plurality of difference parameters of the characteristic values of every two sets of image data. The processing unit accumulates the difference parameters within a predetermined time period to obtain a plurality of accumulated difference parameters corresponding to the pixels. The processing unit determines a plurality of weighting values corresponding to the pixels according to the accumulated difference parameters. The processing unit performs an image processing process according to the sets of image data and the weighting values.

Abstract: An image-capturing apparatus includes: an image sensor and a processor. The processor controls a plurality of pixels included in a first region of the image sensor to accumulate the charges with the light from a subject for a first accumulation time length, and controls a plurality of pixels included in a second region of the image sensor to accumulate the charges with the light from the subject for a second accumulation time length, the second region being different from the first region; and calculates at least one of a movement distance and a speed of a measurement target included in the subject, based on a first image obtained from a first pixel signal group from the plurality of pixels in the first region and a second image obtained from a second pixel signal group from the plurality of pixels in the second region.

Abstract: A method is provided for constructing a composite image. The method comprises illuminating an object with light of a particular spectral band, capturing a digital image of the illuminated object using a monochromatic image sensor of an imaging device to obtain a monochrome image, repeating the steps of illuminating and capturing to obtain a plurality of monochrome images of the object illuminated by light of a plurality of different spectral bands, processing the plurality of monochrome images to generate image data for one or more output channels, and generating a color composite image from the image data. The color composite image comprises the one or more output channels.

Abstract: In various implementations a method includes obtaining a plurality of source images, stabilizing the plurality of source images to generate a plurality of stabilized images, and averaging the plurality of stabilized image to generate a synthetic long exposure image. In various implementations, stabilizing the plurality of source images includes: selecting one of the plurality of source images to serve as a reference frame; and registering others of the plurality of source images to the reference frame by applying a perspective transformation to others of the plurality of the source images.

Abstract: A camera module for an imaging device includes a light sensing module, a control circuit, a mounting member, one or more external lens modules, and a magnetic sensing element. The control circuit sets photographic conditions for a certain external lens module according to a control signal, the control signal being prompted by the magnetic sensing element detecting the type of the external lens module by the arrangement of magnetic components therein, as detected by the magnetic sensing element. The magnetic components have configurations corresponding to the type of the external lens module and the magnetic components assist in aligning one external lens module to the body of the imaging device. The automatic detection and photographic settings applied can be disabled by a user.

Abstract: The present technology relates to an information processing device and an information processing method, a solid-state imaging device and a solid-state imaging device operation method, a program, and an electronic apparatus in which an IC having an AF lens drive control unit mounted therein is made compatible with various communication specifications that vary with the types of lens driver ICs to be connected. A digital analogue converter (DAC) code for controlling a lens driver IC that controls driving of an actuator that drives a focusing lens is generated. A communication format related to serial communication is set in accordance with the lens driver IC, and is stored. The DAC code is buried in the communication format, to form a format compatible with the lens driver IC. Control is performed to cause the DAC code to be transmitted to the lens driver IC through serial communication. The present technology can be applied to imaging apparatuses.

Abstract: Techniques and systems are provided for processing one or more low light images. For example, a short exposure image associated with one or more shutter speeds can be obtained. A long exposure image is also obtained, which is captured using a slower shutter speed than the one or more shutter speeds associated with the short exposure image. An output image can be generated by mapping color information from the long exposure image to the short exposure image.

Abstract: Systems and methods for implementing array cameras configured to perform super-resolution processing to generate higher resolution super-resolved images using a plurality of captured images and lens stack arrays that can be utilized in array cameras are disclosed. An imaging device in accordance with one embodiment of the invention includes at least one imager array, and each imager in the array comprises a plurality of light sensing elements and a lens stack including at least one lens surface, where the lens stack is configured to form an image on the light sensing elements, control circuitry configured to capture images formed on the light sensing elements of each of the imagers, and a super-resolution processing module configured to generate at least one higher resolution super-resolved image using a plurality of the captured images.

Abstract: A system includes a server and a portable electronic device (PED). The server is to store at least one geofence region, and at least one photograph overlay associated with the at least one geofence region. The PED includes a processor to execute an application and connect to the server, and a transceiver coupled to the processor. The transceiver transmits a location of the PED to the server, and receives from the server the at least one photograph overlay based on the location of the PED being within the at least one geofence region. A camera is coupled to the processor to take a photograph, and a display is coupled to the processor to display the photograph with the at least one received photograph overlay.