Abstract: An adaptive lighting system comprises an array of independently controllable LEDs, and a metalens positioned to collimate, focus, or otherwise redirect light emitted by the array of LEDs. The adaptive lighting system may optionally include a pre-collimator positioned in the optical path between the array of LEDs and the metalens.

Abstract: A control device of an imaging device that includes an imaging element which images a subject through a lens device including a vibration-proof lens includes: an image shake correcting unit that corrects an image shake of a captured image output from the imaging element by moving the imaging element or moving an acquisition range of the captured image on a light receiving surface of the imaging element; and a lens position acquiring unit that acquires a position of the vibration-proof lens in a direction perpendicular to an optical axis of the lens device, and the image shake correcting unit controls a movable range of the imaging element or a movable range of the acquisition range based on the position of the vibration-proof lens acquired by the lens position acquiring unit.

Abstract: According to one embodiment, an image processing device includes first storage and a processor. The first storage is configured to store a first statistical model generated by learning bokeh which occurs in a first image. The processor is configured to acquire a second image, acquire a bokeh value which indicates bokeh occurring in the second image and an uncertainty level which indicates a level of uncertainty for the bokeh value, generate a first bokeh map based on the bokeh value and uncertainty level, and acquire a second bokeh map obtained by interpolating a bokeh value with respect to the first bokeh map. The bokeh value and the uncertainty level are output from the first statistical model by inputting the second image into the first statistical model.

Abstract: Systems and methods for characterizing a camera system on a mobile device are disclosed. Characterization of the camera system may be implemented by providing a diffraction pattern of dots at controlled, defined angles to the camera system. Images of the diffraction pattern may be captured during a focus sweep through predetermined focus positions and/or while changing the relative locations between the lens and image sensor at the predetermined focus positions. The captured images may be analyzed to determine calibration data that provides physical measurement of properties of the camera system. The calibration data may then be implemented by the camera system to produce enhanced imaging on the mobile device.

Abstract: A system and method for lightfield communication can be configured to receive one or more images, determine one or more features in the one or more images, and generate a lightfield image from the one or more images where at least one of the one or more features is in a focal plane of the lightfield image.

Abstract: An imaging apparatus includes: a detection unit that detects a pupil in a captured image; an autofocus control unit that executes a pupil autofocus control to perform autofocus on the pupil detected by the detection unit according to a predetermined operation in a still image capturing mode, and executes a pupil autofocus control when the pupil is detected by the detection unit in a moving image capturing mode; and a display control unit that performs a control to display a pupil frame indicating the pupil that is in focus on the captured monitor image when focusing is achieved by the pupil autofocus control.

Abstract: A connector system, ride system and method for connecting and supporting a suspended load. The system includes a suspended carrier having a first connector part and a suspended load support, arranged and disposed to support a suspended load, the suspended load support having a second connector part. A first magnetic coupler is affixed to the suspended carrier and a second magnetic coupler is affixed to the suspended load support. The first magnetic coupler includes a first arrangement of magnets and the second magnetic coupler includes a second arrangement of magnets. The first arrangement of magnets is selectively arranged and disposed to provide alignment and detachable engagement to the magnets of the second arrangement of magnets. The first connector part and the second connector part releasably engage to connect the suspended carrier to the suspended load support and permit transmission of motion, power, signal and at least one utility from the suspended carrier to the suspended load support.

Abstract: Provided are an imaging device, an imaging method, and an imaging program capable of easily acquiring a slow moving image with good image quality. In one aspect of the present invention, an imaging device includes an optical system, an imaging element, and a processor, and the processor performs detection processing of detecting a movement of a subject based on an image signal output from the imaging element, frame rate control of increasing a frame rate of a moving image output from the imaging element based on the detected movement, exposure control processing of maintaining a rate of an exposure time per frame of the moving image constant according to the increase in the frame rate, and dimming control processing of changing a degree of dimming of the optical system according to the exposure control processing.

Abstract: An imaging apparatus includes: an imaging unit that has a pixel region in which a plurality of pixels is arranged and that reads and outputs a pixel signal from the pixels included in the pixel region; a unit-of-readout controller that controls a unit of readout set as a part of the pixel region: a recognition unit that has learned training data for each of units of readout; a first output unit that outputs a recognition result of recognition performed by the recognition unit for each of the units of readout; a second output unit that outputs the pixel signal to a subsequent stage; and a trigger generator that generates a trigger signal for controlling a first timing at which the first output unit outputs the recognition result and a second timing at which the second output unit outputs the pixel signal.

Abstract: An image processing apparatus and method is provided and includes one or more processors; and one or more memories storing instructions that, when executed by the one or more processors, cause the apparatus to receive an input image, determine a position of an estimation area for sharpness estimation based on first information related to a first determination item and not based on second information related to a second determination item if the input image satisfies the first determination item from among a plurality of determination items; determine the position of the estimation area for sharpness estimation based on the second information related to the second determination item if the input image does not satisfy the first determination item and satisfies the second determination item among the plurality of determination items; perform sharpness estimation processing on the determined estimation area; and output a result of the sharpness estimation processing.

Abstract: An image capturing device includes: an image capturing element having a first image capturing region that captures an image of a photographic subject and outputs a first signal, and a second image capturing region that captures an image of the photographic subject and outputs a second signal; a setting unit that sets an image capture condition for the first image capturing region to an image capture condition that is different from an image capture condition for the second image capturing region; a correction unit that performs correction upon the second signal, for employment in interpolation of the first signal; and a generation unit that generates an image of the photographic subject that has been captured by the first image capturing region by employing a signal generated by interpolating the first signal according to the second signal as corrected by the correction unit.

Abstract: A determining method includes acquiring first direction information, when a first captured image captured by an imaging device is acquired, by referring to a storage storing a plurality of pieces of direction information indicating a plurality of directions associating with respective shapes of a plurality of contours of an object according to a plurality of directions of the object, the first direction information associated with a shape of a contour that corresponds to a shape of a contour of the subject included in the acquired first captured image among the shapes of the contours, and acquiring second direction information, when a second captured image newly captured by the imaging device is acquired, by referring to the storage to acquire second direction information associated with a shape of a contour that corresponds to a contour of the subject included in acquired second captured image among the shapes of contours.

Abstract: The present disclosure relates to a solid-state imaging device and an electronic device that can be provided with phase difference pixels with a lower degree of difficulty in manufacturing. Provided is a solid-state imaging device including a pixel array unit in which a plurality of pixels is two-dimensionally arrayed, in which the pixel array unit has an array pattern in which a plurality of pixel groups each including neighboring pixels of an identical color is regularly arrayed, and among the plurality of pixel groups arrayed in the array pattern, pixels configuring a light-shielded pixel group are shielded in an identical direction side from light, the light-shielded pixel group being a pixel group including pixels each being shielded in a part of a light incident side from the light. The present technology can be applied to, for example, a CMOS image sensor including pixels for phase difference detection.

Abstract: An imaging apparatus according to an embodiment includes: an imaging unit (10) having a pixel region in which a plurality of pixels is arranged; a readout controller (11) that controls readout of pixel signals from pixels included in the pixel region; a unit-of-readout controller (123) that controls a unit of readout that is set as a part of the pixel region and for which the readout controller performs the readout; and a recognition unit (14) that has learned training data for each of the units of readout. The recognition unit performs a recognition process on the pixel signal for each of the units of readout, and outputs a recognition result which is a result of the recognition process.

Abstract: A microcomputer estimates information corresponding to an image plane position of an object based on a sequential identification method using a focus detection result. Moreover, the microcomputer predicts information corresponding to a future image plane position of the object based on the estimated information corresponding to the image plane position of the object. The microcomputer controls driving of a focus lens based on the predicted information corresponding to the future image plane position of the object. In accordance with information corresponding to a motion of the object, the microcomputer selects by which of a first Kalman filter and a second Kalman filter the information corresponding to the future image plane position of the object is predicted by using the estimated information corresponding to the image plane position of the object.

Abstract: The present disclosure discloses a method and a system for imaging. The method for imaging objects using the system for imaging. The system for imaging comprises a lens. The objects comprise a first object, a second object and a third object located at different positions on a first preset track. The method for imaging comprises: allowing the lens and the first preset track to move relatively in a first predetermined relationship to acquire a clear image of the third object using the system for imaging without focusing, the first predetermined relationship is determined by a focal plane position of the first object and a focal plane position of the second object. The aforementioned method for imaging is high in imaging efficiency and is capable of fast focusing according to the first predetermined relationship even if focus tracking fails so that the blurring of a photographed image due to defocusing is avoided.

Abstract: The present technology relates to an imaging device, an imaging method, and a program that make it possible to easily perform imaging focusing on a subject or a specific part of the subject. The imaging device causes a preliminary-notice frame that gives notice of a specific area to be focused to be displayed on an image obtained by an imaging unit according to a type of the subject. The present technology can be applied to an imaging device.

Abstract: A photoelectric conversion element for detecting the spot size of incident light, including a photoelectric conversion substrate provided with two main surfaces, and multiple first sensitivity sections and second sensitivity sections arranged in a prescribed direction. When sensitivity regions on the respective main surfaces of the multiple first sensitivity sections are defined as first sensitivity regions, and sensitivity regions that appear on the main surfaces of the second sensitivity sections are defined as second sensitivity regions, each of the first sensitivity regions receives at least a part of light incident on the main surfaces, and has a pattern in which, in accordance with enlargement of an irradiation region irradiated with incident light on the main surface, the proportion of the first sensitivity regions in the irradiation region with respect to the first sensitivity regions other than those in the irradiation region and the second sensitivity regions is decreased.

Abstract: A method for determination of a distance from an observation reference point to an object in a measurement volume that can be utilized in a passive optical remote sensing system, and optical remote sensing systems that utilizes the method.

Abstract: An image sensor and a mobile terminal are provided. The image sensor includes a pixel array, where the pixel array includes a preset quantity of pixel units arranged in a predetermined manner. The pixel unit includes a first pixel and a second pixel. The first pixel includes a red sub-pixel, a green sub-pixel, and a blue sub-pixel, and the second pixel includes a green sub-pixel, a preset sub-pixel, and at least one of a red sub-pixel and a blue sub-pixel. Both the first pixel and the second pixel are full-pixel dual-core focusing pixels, and each of the first pixel and the second pixel includes four full-pixel dual-core focusing sub-pixels. The preset sub-pixel receives an infrared band and one of a red band, a green band, and a blue band, or the preset sub-pixel receives an infrared band, a red band, a green band, and a blue band.

Abstract: Based on captured image data, a detection unit detects a subject area that partially includes a subject to be detected. A control unit performs shooting control based on data corresponding to the subject area among the captured image data, and on a distribution of existence probabilities of the subject in the subject area. The distribution is stored in a memory. The control unit performs the shooting control so that a contribution of data corresponding to a position with a first existence probability is larger than a contribution of data corresponding to a position with a second existence probability that is lower than the first existence probability.

Abstract: An image sensor includes a pixel array including a plurality of pixels arranged in a matrix, each of the pixels including a microlens, a first photoelectric conversion element, and a second photoelectric conversion element, the first and second photoelectric conversion elements being arranged parallel with each other in a first direction below the microlens; and a row decoder configured to control a first image signal generated by the first photoelectric conversion element and a sum image signal generated by the first and second photoelectric conversion elements to be sequentially output from a first pixel in a first row of the pixel array during a first readout period, and to control a second image signal generated by the second photoelectric conversion element and the sum image signal to be sequentially output from a second pixel in a second row of the pixel array during a second readout period.

Abstract: The present disclosure provides a method for adjusting a position of a photosensitive chip of an image acquisition device. The method may include determining a first symmetrical axis and a second symmetrical axis of the photosensitive chip. The first symmetrical axis may divide the photosensitive chip into a first portion and a second portion, and the second symmetrical axis may divide the photosensitive chip into a third portion and a fourth portion. The method may further include adjusting the position of the photosensitive chip from an initial position to an adjusted position. When the photosensitive chip is at the adjusted position, a first image resolution corresponding to the first portion may be substantially equal to a second image resolution corresponding to the second portion, and a third image resolution corresponding to the third portion may be substantially equal to a fourth image resolution corresponding to the fourth portion.

Abstract: Example methods and systems to obtain images associated with target cells distributed in a cytology specimen have been disclosed. One example method includes obtaining a first image associated with a first region of the cytology specimen through a first object lens, determining a first subregion of the first region, obtaining a second set of one or more images associated with the first subregion through a second object lens, identifying a third image from the first image, and in response to a ratio of a second number of the target cells in the second set of one or more images to the first number of the target cells in the third image being in a predetermined range, obtaining images associated with the target cells based on the second set of images.

Abstract: Examples of capturing and processing image data are described. A device may include a camera including a camera sensor that includes a plurality of tiles that each include four sub-tiles. The camera may also include a color filter array coupled to the camera sensor and including a plurality of red, blue, and green color filters. A first sub-tile of each tile may include a phase detection pixel coupled to a microlens shared with at least one other pixel of the tile and an imaging pixel not coupled to a second microlens different from the first microlens. The device may also include a processor coupled to the camera and configured to control one or more first exposure settings of the phase detection pixel and control one or more second exposure settings of the non-phase detection pixel. Control of the second exposure settings is independent from control of the first exposure settings.

Abstract: An intra-oral scanning device includes a light source and an optical system, and communicates with a display system. The device provides for more efficient transmission and capture of images. It integrates OCT scanning with RGB-based scanning. In operation, the device is used for recording topological characteristics of teeth, dental impressions, or stone models by digital methods and for use in CAD/CAM of dental restorative prosthetic devices. To that end, the RGB-based scan obtains surface data (e.g., a margin), while the OCT scan penetrates the surface. The two scanners operate from within the same physical housing and preferably at the same time such that only one scanning pass (to obtain all necessary data) is required. The 3D data obtained from the OCT scan is registered with the 3D data obtained from the RGB-based scan by virtue of being captured using a common return path.

Abstract: A system and method for lightfield communication can be configured to receive one or more images, determine one or more features in the one or more images, and generate a lightfield image from the one or more images where at least one of the one or more features is in a focal plane of the lightfield image.

Abstract: An image capture apparatus that detects, from an image, a subject area and a characteristic area within the subject area is disclosed. The image capture apparatus sets an AF area to the characteristic area and detects a defocus amount for the AF area and defocus amounts for peripheral areas of the AF area. The image capture apparatus corrects the defocus amount detected for the AF area based on the defocus amounts detected for the peripheral areas and adjusts focus of an imaging optical system based on the corrected defocus amount.

Abstract: The present disclosure generally relates to user interfaces for altering visual media. In some embodiments, user interfaces capturing visual media (e.g., via a synthetic depth-of-field effect), playing back visual media (e.g., via a synthetic depth-of-field effect), editing visual media (e.g., that has a synthetic depth-of-field effect applied), and/or managing media capture.

Abstract: This application provides a lens module and a lens module control method to implement, among other features, automatic focusing and improve image definition. The lens module includes an imaging lens, a first control module, a first processing module, a liquid lens, and an image chip. The liquid lens is configured to refract an imaging beam that comes from the imaging lens, and the liquid lens comprises a transparent first flat lens and a transparent second flat lens that are parallel to each other. The first control module is configured to adjust a distance between the first flat lens and the second flat lens. The first processing module is configured to adjust a distance between the first flat lens and the second flat lens by using the first control module and based on a definition of the digital image, so as to adjust the definition of the image generated by the image chip.

Abstract: An electronic device according to various embodiments of the present invention may comprise: a camera including a lens assembly having one or more lenses, and a driving unit that can adjust focus by moving at least some of the lenses (a portion of the lenses) of the lens assembly; a memory; and a processor operatively connected to the lens assembly, the camera, and the memory.

Abstract: Provided are a focus adjustment operation detection device, a focus adjustment operation detection method, a focus adjustment operation detection program, an imaging device main body, and an imaging device capable of accurately detecting a focus adjustment operation of an imaging lens. An optical image passed through the imaging lens is received, and a phase difference of the received optical image is detected for each of a plurality of divided areas. Whether or not the focus adjustment operation of the imaging lens is performed is detected based on the amount of change in the phase difference for each divided area.

Abstract: The present disclosure provides a system and method for medical image visualization. The method may include obtaining original image data of a subject, the original image data including a first region of interest (ROI) and a second ROI. The method may also include generating first image data associated with the first ROI according to a first instruction, and causing the first ROI to be displayed on a display device as a first image based on the first image data. The method may further include generating, according to a second instruction, second image data corresponding to a target region that includes the second ROI, updating the first image data based on the second image data, and causing the second ROI to be displayed on the display device as a second image based on the updated first image data.

Abstract: An imaging apparatus includes an imager and a controller, wherein the controller calculates the evaluation value over a detection range with respect to position of the focus lens to perform the focusing operation, and in response to an instruction to reduce or increase a distance to a subject to be focused, the controller sets, in the detection range with respect to position of the focus lens, a region including a position close to a closest end or an infinite end with respect to a current position of the focus lens according to a direction specified by the instruction, as a focusing region, and adjusts the position of the focus lens within the set focusing region in the focusing operation.

Abstract: Methods and apparatus for implementing a camera having a depth which is less than the maximum length of the outer lens of at least one optical chain of the camera are described. In some embodiments a light redirection device, e.g., a mirror, is used to allow a relatively long optical chain with a relatively large non-circular outer lens. In some embodiments the light redirection device has a depth, e.g., front of camera to back of camera dimension, which is less than the maximum length of the aperture of the outer lens in the aperture's direction of maximum extent. Multiple optical chains with non-circular outer lenses arranged in different directions may and in some embodiments are used to capture images with the captured images being combined to generate a composite image.

Abstract: A control method for a mobile platform includes obtaining a captured image, identifying one or more candidate first characteristic parts from the captured image, determining a second characteristic part of a target object in the captured image, determining one or more matching parameters each corresponding to one of the one or more candidate first characteristic parts based on the one or more candidate first characteristic parts and the second characteristic part, determining a target first characteristic part of the target object from the one or more candidate first characteristic parts based on the one or more matching parameters, and switching from tracking the second characteristic part to tracking the target first characteristic part in response to a tracking parameter of the target object meeting a preset tracking condition.

Abstract: Provided is a display apparatus including a plurality of light-emitting diode (LED) display modules, wherein each of the plurality of LED display modules includes a plurality of LED pixels; and a controller that controls operation of each of the plurality of LED pixels, wherein each of the plurality of LED pixels is connected to the controller via a different driving signal line, and at least two of the plurality of LED pixels are connected to the controller via a same power line.

Abstract: There are provided an imaging device, an information acquisition method, and an information acquisition program that can simply and accurately acquire information related to a ray angle with respect to an image sensor in a case where subject light is incident on the image sensor through an interchangeable lens even though the interchangeable lens having no compatibility is mounted on the imaging device.

Abstract: A distance measurement device including a pixel array and a cover layer is provided. The cover layer is covered on the pixel array. The cover layer includes a first cover pattern covering on a first area of a plurality of first pixels and a second cover pattern covering on a second area of a plurality of second pixels. The first area and the second area are rectangles of mirror symmetry along a first direction.

Abstract: A camera module includes a lens barrel, a driving coil disposed to face a target detection unit disposed on one side of the lens barrel, a driving device to provide a driving signal to the driving coil, and a position calculating unit including a capacitor, constituting an oscillation circuit together with the driving coil, to calculate a position of the lens barrel from an oscillation signal output by the oscillation circuit. The position calculating unit generates an alternating current (AC) signal according to a comparison result of a peak of the oscillation signal and a reference peak and calculates a position of the lens barrel according to a frequency of the AC signal.

Abstract: The presently disclosed subject matter includes a mobile electronic comprising an integrated camera, comprising a Wide camera unit comprising a Wide lens unit, and a Telephoto camera unit comprising a telephoto lens unit, the telephoto lens unit and the wide lens unit having respectively TTL/EFL ratios smaller and larger than 1 and defining separate telephoto and wide optical paths.

Abstract: An image sensor, a focusing control method, and an electronic device are disclosed. The image sensor includes: a photosensitive unit array, a filter unit array disposed above the photosensitive unit array, and a micro-lens array located above the filter unit array. The photosensitive cell array includes one or more focusing photosensitive cells and multiple non-focusing photosensitive cells. Each of the focusing photosensitive cells includes multiple photosensitive pixels. The micro-lens array includes one or more first micro-lenses and multiple second micro-lenses; wherein each of the focusing photosensitive cells is covered by a corresponding one of the first micro-lenses, and each of the non-focusing photosensitive cells is covered by N*N of the second micro-lenses; wherein N is a positive integer.

Abstract: The present disclosure provides a photography processing method for a camera module, a terminal, and a computer-readable storage medium. The method includes: controlling the photosensitive unit array to enter a focusing mode; reading a first set of output values of the M pairs of first focusing photosensitive units; reading a second set of output values of the N pairs of second focusing photosensitive units; performing focusing control according to the first set of output values and the second set of output values.

Abstract: There is provided an image processing apparatus. An obtaining unit obtains a distance map and a shot image, the distance map representing a distribution of information related to a distance in a depth direction of a shooting range using a distribution of distance values, the shot image corresponding to the shooting range. A first filter unit applies a first filter to the distance map. A second filter unit applies a second filter to the distance map to which the first filter has been applied. The first filter is a filter that reduces a distribution of distance values in a predetermined distance value range in the distance map. The second filter is a filter that changes a distance value of a target distance in the distance map using weighted averaging.

Abstract: A series of frames or live images received by a camera can be processed by an automatic image capture system to determine when an automatic image capture should take place. The system can detect when a scene change occurs by comparison of data for two or more frames. If a scene change is followed by a stabilization of the scene, the system can trigger an auto-capture of the stabilized scene, without the need for user input.

Abstract: A compact adaptive optics system for long-range horizontal paths imaging that improves degraded images. The system uses a filter that corresponds to the three colors in a typical color detector element, one or more optic elements, a deformable mirror, and a detector. Focus errors, due to turbulence, in the image recorded by the detector element show up as image shifts in the three distinct color images. The shifts and statistics of these shifts between these simultaneous images are used to create control signals for the deformable mirror resulting in a compact adaptive optic system for horizontal paths without need for a point source located at the distance scene being imaged. Analysis of the relative pixel shifts in various regions of the image provides third order statistics revealing tip/tilt and additional Zernikes modes that are used to control a deformable mirror without the need for a guide star/point-source.

Abstract: An image capturing apparatus, comprises a detector configured to detect a focus adjustment position in an image, a processor configured to generate a composite image in which a guide indicating the detected position is superimposed on the image, a display configured to display the composite image generated by the processor, and a controller configured to update, in accordance with information of the position detected by the detector, display information used for processing for generating the composite image.

Abstract: A device can identify a tracking device; identify, in an image or video and using a computer vision technique, a tracked asset or an identifier associated with the tracked asset, wherein the tracking device is to be used to track a location of the tracked asset; determine information identifying an association between the tracking device and the tracked asset based on identifying the tracking device and identifying, in the image or video and using the computer vision technique, the tracked asset or the identifier associated with the tracked asset; determine a link between the tracking device and the tracked asset based on the information identifying the association between the tracking device and the tracked asset; and store or provide link information that identifies the link between the tracking device and the tracked asset to track the location of the tracked asset using the tracking device.

Abstract: Disclosed are an image processing apparatus that can efficiently suppress the data amount of data indicating a spatial distribution and an angular distribution of light intensity and a control method of the same. The image processing apparatus obtains data indicating the spatial distribution and the angular distribution of the intensity of light beams that have passed through partial pupil areas obtained by dividing the exit pupil of an imaging optical system into a predetermined number. The image processing apparatus then reduces the bit depth or the number of tones of signals constituting the data based on the predetermined number.

Abstract: An image capturing apparatus comprising: an image sensor that includes a plurality of focus detection pixels capable of outputting a pair of signals to be used for focus detection; a setter that sets an exposure control value based on a result of photometry; a controller that controls to perform image shooting by controlling exposure based on the exposure control value set by the setter; a detector that detects a focus state based on the pair of signals read out from the plurality of focus detecting pixels under control of the controller; and an estimator that estimates reliability of the focus state detected by the detector by normalizing an evaluation value obtained at a time of detecting the focus state by the detector in a case where the image shooting is performed using the exposure control value set by the setter.