Abstract: An image processing apparatus generates a normal image, when lighting correction of an image is performed using three-dimensional shape data. Three-dimensional shape data of a predetermined object is adjusted with a subject in position, based on a feature pattern detected in image data, and lighting processing for correcting a pixel value of the image data is performed based on the adjusted three-dimensional shape data, distance information of the subject, and a position of a virtual light source. When the three-dimensional shape data is adjusted with the image data in position, a region having a large irregularity in the three-dimensional shape data is preferentially adjusted in position.

Abstract: A projection control apparatus is configured to control a first image projection apparatus that projects a first image and a second image projection apparatus that projects a second image so that the first image and the second image are superimposed on each other in a predetermined area. The projection control apparatus includes a corrector configured to correct an imaging characteristic for converting a received light amount into captured image data in an imaging apparatus configured to capture the first and second images, by using a pixel value of the predetermined area in the captured image data obtained from the imaging apparatus, and a controller configured to control at least one of the first and second image projection apparatuses using a corrected imaging characteristic.

Abstract: An imaged image obtaining section obtains an imaged image from a camera. A face recognizing section detects the face images of a plurality of users in the imaged image. A display user determining section has a function of determining a user to be included in a display image. When an instruction receiving section receives a changing instruction, the display user determining section changes a user included in the display image. A face image clipping section clips a region including the face image of the determined user from the imaged image. A display image generating section generates the display image including the clipped region.

Abstract: A circuit arrangement includes a buffer, a height traversal circuit configured to generate a sequence of IFM height values in response to first control signals, a width traversal circuit configured to generate a sequence of IFM width values in response to second control signals, a control circuit, and an address generation circuit. The control circuit is configured to input an OFM height, an OFM width, a kernel height, and a kernel width; generate the first control signals at times based on the OFM height and the kernel height; and generate the second control signals at times based on the OFM width and the kernel width. The address generation circuit is configured to generate a sequence of addresses based on the sequences of IFM height values and IFM width values, provide the sequence of addresses to the buffer, and enable reading from the buffer.

Abstract: Presented here is a system and method to record images having varying zoom levels using a lens having a substantially fixed zoom level. The resulting image can have varying zoom levels and can be of high quality. The light sensor recording the image can have a resolution higher than the desired resolution of the resulting image. The high resolution of the light sensor allows digital zooming, i.e., cropping of the image. The light sensor can operate in two modes, where each mode produces varying resolutions of the resulting image. Operating the light sensor in the mode producing a high resolution of the resulting image, however, does not produce images of satisfactory quality in low light conditions, and the light sensor may need to be switched between the first and the second mode depending on the zoom level and the lighting conditions.

Abstract: A method for capturing a high-dynamic-range image includes: (i) storing a plurality of pixel values representing a first image captured by an image sensor that includes a pixel array, each pixel value having been generated by a respective pixel of a pixel subarray of the pixel array, each pixel being set to one of N1 first exposure values, N1?1; (ii) determining an exposure-count N2 based on the plurality of pixel values; (iii) setting each pixel to one of a second plurality of exposure values, N2 in number, such that, for each of the second plurality of exposure values, at least one pixel is set to that exposure value, one of the second plurality of exposure values differing from each of the N1 first exposure values by more than a threshold value; and after setting (iv), capturing a second image with the image sensor.

Abstract: A zoom lens includes, in order from an object side, a positive first unit, a negative second unit, a positive intermediate group consisting of one or two units and including a third unit located on a most object side, a negative unit, and a rear group consisting of one or two units including a positive unit located on a most object side. Conditional expressions are satisfied with respect to amounts of movement of the second and third units from a wide angle end to a telephoto end, a distance at the wide angle end from a most object side surface vertex in the first unit to a most object side surface vertex in the third unit, an Abbe number of a most object side lens in the first unit, a focal length of the second unit, and focal lengths at the wide angle end and at the telephoto end.

Abstract: The present invention discloses a motion detection circuit applied to CIS and a motion detection method.

Abstract: An imaging apparatus includes a solid-state image sensor with Bayer array structure. The imaging apparatus includes a calculation circuit, an interpolation operating circuit, and a G-step detecting circuit. The calculation circuit calculates a first value and a second value, for each predetermined image area of image data output from the solid-state image sensor. The first value is a mean value or integrated value of pixel values of first green pixels. The second value is a mean value or integrated value of pixel values of second green pixels. The interpolation operating circuit performs, for a plurality of the image areas, an interpolation operation by using a plurality of the first values and a plurality of the second values.

Abstract: Example embodiments are directed to a system of image enhancement. An interface device is configured to receive as input one or more input images. The one or more input images have one or more exposure values. A processing device is configured to execute an exposure value (EV) resampling module to generate one or more resampled images having exposure values different from the one or more exposure values of the one or more input images. The resampled images have a range of exposure values. The processing device is configured to execute a filtering module to filter the resampled images, and output a set of filtered images. The processing device is configured to execute a blending module to sequentially blend the set of filtered images, and output a merged image.

Abstract: A radiation image detector is provided. The radiation image detector includes: a substrate, an optical image detector located on the substrate and including an array including photosensitive pixels, a radiation conversion layer, and pixelated light-collecting structures located between the photosensitive pixels and the radiation conversion layer and configured to guide visible light that would fall into a trench region or a side wall region to a central region. Each photosensitive pixel includes a first electrode including a first contact surface in direct contact with the photoelectric conversion layer, a photoelectric conversion layer including the central region and the side wall region, and a second electrode including a second contact surface in direct contact with the photoelectric conversion layer.

Abstract: An object of the present invention is to estimate the shape of an object easily and with a high accuracy. The present invention is a generation apparatus including: an acquisition unit configured to acquire a plurality of pieces of image data obtained by capturing an object from different directions by a plurality of image capturing apparatuses arranged at different positions, respectively; a first derivation unit configured to derive reliability for each of the image capturing apparatuses based on spatial resolution in the image data; and a generation unit configured to generate three-dimensional shape data representing the shape of the object based on the image data and the reliability.

Abstract: The present disclosure provides an image sensor circuit, including: a pixel array, including a plurality of pixel series, where a pixel series in the plurality of pixel series includes a plurality of pixel circuits; and a clock signal generating circuit, coupled to a first end and a second end of the pixel series; where a first clock signal is propagated from the first end of the pixel series to the second end of the pixel series at a first time; and where a second clock signal is propagated from the second end of the pixel series to the first end of the pixel series.

Abstract: An image acquisition unit configured to acquire an image obtained by performing image capturing of a subject using an imaging unit, a detection method setting unit configured to set a detection method of a subject for the image, a subject detection unit configured to detect a subject based on the detection method determined by the detection method setting unit, and an exposure determination unit configured to determine exposure based on a detection result obtained from the subject detection unit are included, and the detection method setting unit can set the detection method different for each of different regions in the image, based on predetermined information used in performing image capturing for obtaining the image.

Abstract: An image-pickup apparatus suppresses noise at a high speed while reducing power consumption by controlling the number of sampling operations in signal processing for suppressing noise of an imaging element. The image-pickup apparatus of the present invention includes an imaging element having a plurality of pixel units, a control unit performing first control of acquiring a first signal that is a noise signal from the pixel units and second control of acquiring a second signal based on signal charge generated by photoelectric conversion units of the pixel units, and a signal processing unit subtracting the first signal from the second signal, and the control unit performs control of changing the number of sampling operations of the second signal.

Abstract: An information processing apparatus includes a memory and a processor coupled to the memory that obtains projection information used for generating a three-dimensional overhead image by projecting a plurality of image data imaged by a plurality of imaging devices to a three-dimensional projection surface when the plurality of imaging devices are installed in a first mobile object, that inputs size information of a second mobile object that is different from the first mobile object, that corrects the projection information based on a size ratio between the first mobile object and the second mobile object, calculated based on the size information of the second mobile object, and that stores corrected projection information in the second mobile object.

Abstract: Determining a focus setting includes determining a plurality of regions of interest in a view of a scene, and, for each of the plurality of regions of interest, obtaining a set of image data for each of multiple focal positions, and then applying focus filters to the set of image data for each of the plurality of focal positions for each of the regions of interest to obtain a set of focus scores, i.e., a focus score for each focus filter applied to the set of image data for each of the focal positions. Further, determining a confidence value associated with each of the sets of focus scores, selecting a subset of the sets of focus scores based on the confidence values associated with each of the sets of focus scores, and determining a focus setting for the scene based on the selected subset of the focus scores.

Abstract: The present disclosure relates to system(s) and method(s) for testing an electronic device. The system may receive a configuration file from a user device. Further, the system may operate the electronic device under test based on a target test case selected from the configuration. The system may further operate a video capturing device to capture a sequence of video frames of visual indicators corresponding to the electronic device under test. The system may further analyse the sequence of video frames to identify one or more target video frames indicating visual change in the visual indicators corresponding to the electronic device. The may further analyse the one or more target video frames to determine response time corresponding to each target video frame. Furthermore, the system may generate a test report based on the response time corresponding to the one or more target video frames.

Abstract: A dynamic vision sensor (DVS) or change detection sensor reacts to changes in light intensity and in this way monitors how a scene changes. This disclosure covers both single pixel and array architectures. The DVS may contain one pixel or 2-dimensional or 1-dimensional array of pixels. The change of intensities registered by pixels are compared, and pixel addresses where the change is positive or negative are recorded and processed. Analyzing frames based on just three values for pixels, increase, decrease or unchanged, the proposed DVS can process visual information much faster than traditional computer vision systems, which correlate multi-bit color or gray level pixel values between successive frames.

Abstract: A method and apparatus of processing and displaying images captured using an in vivo capsule camera are disclosed. One or more overlapped areas between a target image and each image in a neighboring image group are determined, which comprises at least two neighboring images around the target image. Marked pixels in the target image are then determined, where a pixel in the target image is designated as a marked pixel if the pixel is within an overlapped area between the target image and at least one neighboring image. If the total number of the marked pixels in the target image exceeds a threshold and the number of the marked pixels associated with the overlapped area(s) between the target image and any image in the neighboring image group is below the threshold, the target image is excluded from a set of images to be displayed on a display device.

Abstract: The present disclosure relates to methods, systems, and apparatuses for identifying related records in a database. The method includes receiving, via a network interface, a related records query, the related records query identifying at least one record stored in the electronic database, determining, based on transaction data, at least one related record that is related to the identified at least one record, determining, by a processor, that the at least one related record is unavailable, in response to determining that the at least one related record is unavailable, determining at least one keyword associated with the at least one related record, selecting at least one of one or more substitute records based at least in part on comparing the at least one keyword with a set of keywords associated with one or more substitute records, and providing the selected one or more substitute records as a response to the related records query.

Abstract: Disclosed in embodiments of the present application are a QR code generation method and apparatus for a terminal device. The terminal device comprises a camera. A specific implementation mode of the method comprises: receiving a QR code generation instruction input by a user, wherein the QR code generation instruction comprises a QR code information; starting a camera, and generating a camera real-time photographing picture; and generating a real-time picture displaying the QR code based on the QR code information and the generated camera real-time photographing picture. The implementation mode enables the user to clearly distinguish whether the QR code is an originally generated QR code, thereby improving the security of the QR code.

Abstract: An image is processed appropriately even in a case that the image includes multiple correction areas. In a case of performing the correction processing for each of a first correction area and a second correction area, a controller (40) determines whether to perform suppression processing of suppressing the correction processing for at least one of the first correction area or the second correction area depending on a distance between the inner area of the first correction area and the inner area of the second correction area.

Abstract: In some embodiments, an image processing application executing on a processing device detects an object in an image that is in a field of view of a camera associated with the processing device. The image processing application further determines, based on the object detected in the image, a recommended filter for the image from a list of filters available for filtering the image. The image processing application causes a display device to display a user interface that includes a contextual user interface control. The contextual user interface control indicates that a context-aware image filtering mode is available for the image. Responsive to receiving a selection of the contextual user interface control, the image processing application enables the context-aware image filtering mode by automatically applying the recommended filter to the image to generate a filtered image and causes the display device to display the filtered image.

Abstract: The discussion relates to 4D tracking. One example can utilize multiple 3D cameras positioned relative to an environment to sense depth data of the environment from different viewpoints over time. The example can process the depth data to construct 3D solid volume representations of the environment, select subjects from the 3D solid volume representations, and recognize actions of the selected subjects.

Abstract: An example operation includes one or more of receiving, by a server, first data related to a damaged portion of a transport from one or more of the transport and one or more devices in proximity to the transport, analyzing, by the server, the first data to determine missing data related to the damaged portion, and requesting, by the server, the missing data from one or more other devices in first proximity to the transport when damage occurred to the damaged portion.

Abstract: A method for controlling the front camera includes: an operation instruction for the front camera is received from an application; a trigger message is sent to a pop-up motor service to trigger the pop-up motor service to control a pop-up or retraction of the front camera; and the front camera is controlled based on the operation instruction to perform a corresponding operation.

Abstract: A method for multi-frame blending includes obtaining at least two image frames of a scene. One of the image frames is associated with a shorter exposure time and a higher sensitivity and representing a reference image frame. At least one other of the image frames is associated with a longer exposure time and a lower sensitivity and representing at least one non-reference image frame. The method also includes blending the reference and non-reference image frames into a blended image such that (i) one or more motion regions of the blended image are based more on the reference image frame and (ii) one or more stationary regions of the blended image are based more on the at least one non-reference image frame.

Abstract: Methods and systems for organizing media. The systems and methods described herein organize media items based on metadata and unique media item content attributes. If a media item satisfies one or more criteria, the media item is transferred to an album to be shared with authorized users.

Abstract: Methods, systems, and apparatuses are provide to perform automatic banding correction in captured images. For example, the methods receive from a plurality of sensing elements in a sensor array, first image data captured with a first exposure parameter, and second image data captured with a second exposure parameter. The methods partition first image data and second image data and determine values for each partition. The methods compute banding errors based on the determined values of the partitions for first image data and second image data. The methods also determine a banding error correction to one or more of first image data and second image data based on the banding errors. Further, the methods perform an automatic correction of the banding errors on one or more of first image data and second image based on the banding error correction.

Abstract: Aspects of this disclosure include technologies for appearance-flow-based image generation. In applications for pose-guided person image generation or virtual try-on, the disclosed system can model the appearance flow between source and target clothing regions. Further, a cascaded appearance flow estimation network is used to progressively refine the appearance flow. The resulting appearance flow can properly encode the geometric changes between the source and the target for image generation.

Abstract: An image pickup apparatus includes an image pick-up unit configured to pick up a plurality of first images and at least one second image, a combining unit configured to extract a focused part from each of the plurality of first images to generate a first composite image, and a display configured to display the first composite image, wherein the combining unit further extracts focused parts from the first composite image and the at least one second image to generate a second composite image.

Abstract: Systems and methods are disclosed for high dynamic rate processing based on angular rate measurements. For example, methods may include receiving a short exposure image that was captured using an image sensor; receiving a long exposure image that was captured using the image sensor; receiving an angular rate measurement captured using an angular rate sensor attached to the image sensor during exposure of the long exposure image; determining, based on the angular rate measurement, whether to apply high dynamic range processing to an image portion of the short exposure image and the long exposure image; and responsive to a determination not to apply high dynamic range processing to the image portion, selecting the image portion of the short exposure image for use as the image portion of an output image and discard the image portion of the long exposure image.

Abstract: Provided is a semiconductor chip and an electronic apparatus that can suppress degradation of optical characteristics of a semiconductor chip including an image pickup device. The semiconductor chip includes an image pickup device, a transparent protective member that protects the image pickup device, an IR cut film arranged between a light-receiving surface of the image pickup device and the protective member, a bonding layer that bonds the IR cut film and the protective member together, and a protective film that covers side surfaces of the IR cut film and the bonding layer.

Abstract: Methods and apparatus of processing 360-degree virtual reality images are disclosed. According to one method, the method receives coded data for an extended 2D (two-dimensional) frame including an encoded 2D frame with one or more encoded guard bands, wherein the encoded 2D frame is projected from a 3D (three-dimensional) sphere using a target projection, wherein said one or more encoded guard bands are based on a blending of one or more guard bands with an overlapped region when the overlapped region exists. The method then decodes the coded data into a decoded extended 2D frame including a decoded 2D frame with one or more decoded guard bands, and derives a reconstructed 2D frame from the decoded extended 2D frame.

Abstract: A device may include a memory storing instructions and a processor configured to execute the instructions to receive, from a configuration client device, a request to register a resource; and identify a domain object associated with the resource, wherein the domain object corresponds to a logical entity representing a device or port, or corresponds to a logical entity controlling another resource included in another domain object. The processor may be further configured to select a domain object handler for the identified domain object; register the identified domain object with the selected domain object handler; and use the selected domain object handler to process messages associated with the registered domain object.

Abstract: A communication terminal includes circuitry that displays a first image corresponding to a first area of a whole image shared by communication terminals, and stores first terminal information identifying a first one of the communication terminals that causes a second one of the communication terminals to display an image being displayed by the first communication terminal. The circuitry receives second terminal information and viewable area information from a third one of the communication terminals that displays a second image corresponding to a second area of the whole image. The second terminal information identifies the third communication terminal. The viewable area information represents the second area. When the first terminal information and the second terminal information are the same, the circuitry determines whether an operation state of the first image is an operating state, and if so, displays the second image after the operation state shifts to a standby state.

Abstract: The present disclosure provides systems and methods for virtual facial makeup simulation through virtual makeup removal and virtual makeup add-ons, virtual end effects and simulated textures. In one aspect, the present disclosure provides a method for virtually removing facial makeup, the method comprising providing a facial image of a user with makeups being applied thereto, locating facial landmarks from the facial image of the user in one or more regions, decomposing some regions into first channels which are fed to histogram matching to obtain a first image without makeup in that region and transferring other regions into color channels which are fed into histogram matching under different lighting conditions to obtain a second image without makeup in that region, and combining the images to form a resultant image with makeups removed in the facial regions.

Abstract: Provided is an image processing device that acquires a stereo image captured by a plurality of cameras each including a wide-angle lens, divides viewing angles of the cameras with reference to optical axes corrected to be parallel to each other, generates a plurality of base images in each of which a range of each divided viewing angle is reflected and a plurality of reference images on a basis of wide-angle images constituting the stereo image, applies projective transformation to the reference images, and calculates a distance to a predetermined object on a basis of corresponding image pairs of the plurality of base images and the plurality of reference images after projective transformation.

Abstract: An electronic device includes a control unit configured to perform control to: in a first state where a first selectable candidate group is assigned to an current candidate group, switch from selecting a first candidate of the first candidate group to selecting a second candidate of the first candidate group in response to an first type operation of a specific operating member; in the first state, change from the first state to a second state, where a second selectable candidate group is assigned to the current candidate group, in response to a second type operation of the specific operating member; in the second state, switch from selecting a first candidate of the second candidate group to selecting a second candidate of the second candidate group in response to the first type operation of the specific operating member.

Abstract: [Object] To provide a display control apparatus that can perform control of displaying an auxiliary line serving as aid for composition decision that satisfies the demand of the user. [Solution] Provided is a display control apparatus including: a control unit configured to control a display mode on a screen of an auxiliary line serving as aid for composition decision at a time of image capturing, in accordance with the operation of a user that is performed on a screen. The display control apparatus can perform control of displaying an auxiliary line serving as aid for composition decision that satisfies the demand of the user.

Abstract: Provided is a display control apparatus including: a control unit that performs control of displaying a plurality of representative images extracted from a search target image group, and image group information that indicates presence of an image other than the representative images in the search target image group and is displayed in a form different from the representative images between a plurality of the representative images.

Abstract: A construction machine includes a boom, an operator cab, a distance sensor, a displacement detection unit, a storage unit, and a position information acquisition unit. The distance sensor has a predetermined field of view and acquires distance image data indicating a distance distribution of an environment around the operator cab. The storage unit stores initial position information of the boom. The displacement detection unit compares comparative position information of the boom, the comparative position information being acquired from the distance image data by the position information acquisition unit, with initial position information of the boom stored in the storage unit to detect a displacement of the distance sensor with respect to the operator cab when the boom is brought into an initial posture again after initial setting.

Abstract: An image processing apparatus for an endoscope includes processing circuitry. The processing circuitry acquires a left image and right image. The processing circuitry generates a three-dimensional display image based on the left image and right image. The processing circuitry sets a first region in a part of the left image or right image. The first region is a region having a blur. The processing circuitry sets a second region in the left image or right image. The second region is a region where the user is performing treatment. The processing circuitry computes an overlapping region between the first region and the second region. The processing circuitry determines whether or not to notify the user based on the overlapping region. The processing circuitry generates information for notifying.

Abstract: An image capturing apparatus includes a pixel portion in which a plurality of pixel blocks are arranged, each pixel block including a predetermined number of pixels; a plurality of readout circuits arranged corresponding to the plurality of pixel blocks; a supply unit that supplies drive signals to the plurality of readout circuits; a setting unit that sets image capturing conditions for each of the plurality of pixel blocks; and a control unit that carries out control so that when the setting unit has set different image capturing conditions for a first pixel block and a second pixel block, the supply unit supplies a first drive signal to the readout circuits corresponding to the first pixel block, and supplies a second drive signal to the readout circuits corresponding to the second pixel block.

Abstract: Embodiments relate to image signal processors (ISP) that include binner circuits that down-sample an input image. An input image may include a plurality of pixels. The output image of the binner circuit may include a reduced number of pixels. The binner circuit may include a plurality of different operation modes. In a bin mode, the binner circuit may blend a subset of input pixel values to generate an output pixel quad. In a skip mode, the binner circuit may select one of the input pixel values as the output pixel pixel. The selection may be performed randomly to avoid aliasing. In a luminance mode, the binner circuit may take a weighted average of a subset of pixel values having different colors. In a color value mode, the binner circuit may select one of the colors in a subset of pixel values as an output pixel value.

Abstract: The present disclosure relates to a solid-state imaging element configured to inhibit an adverse effect, which is attributable to a light shielding film formed for disposing an OPB region, on the formation of a constituent other than the light shielding film of the solid-state imaging element, and an electronic device. According to a first aspect of the present disclosure, there is provided a solid-state imaging element, including: an effective pixel region in which a large number of pixels are vertically and horizontally arranged; and an OPB region formed by coating pixels around the effective pixel region with a light shielding film. Corners on at least one of an outer circumferential side and an inner circumferential side of the OPB region are formed into an arc shape. The present disclosure can be applied to, for example, a back-surface irradiation type CMOS image sensor.

Abstract: An image processing system includes: a plurality of imaging devices each of which includes an image processing unit that executes image processing including development processing of RAW data obtained by imaging; and an information processing device that acquires power supply information regarding power supply states of the plurality of imaging devices, selects the imaging device that executes the development processing according to the power supply state represented by the acquired power supply information, and causes the selected imaging device to execute the development processing.

Abstract: A solid-state imaging device includes a plurality of pixels each of which includes a photoelectric conversion unit that generates charges by photoelectrically converting light, and a transistor that reads a pixel signal of a level corresponding to the charges generated in the photoelectric conversion unit. A phase difference pixel which is at least a part of the plurality of pixels is configured in such a manner that the photoelectric conversion unit is divided into a plurality of photoelectric conversion units and an insulated light shielding film is embedded in a region for separating the plurality of photoelectric conversion units, which are divided, from each other.

Abstract: A multi-aperture imaging system comprising a first camera with a first sensor that captures a first image and a second camera with a second sensor that captures a second image, the two cameras having either identical or different FOVs. The first sensor may have a standard color filter array (CFA) covering one sensor section and a non-standard color CFA covering another. The second sensor may have either Clear or standard CFA covered sections. Either image may be chosen to be a primary or an auxiliary image, based on a zoom factor. An output image with a point of view determined by the primary image is obtained by registering the auxiliary image to the primary image.