A technique for reducing a work load during introduction of a system in the system processing an image generated by a camera. An information processing apparatus includes at least an accumulation unit, a recommended setting determination unit, and a camera control unit. The accumulation unit accumulates a score obtained through an authentication process using an image in which a person is captured and a camera setting at which a camera generates the image in a storage area. The recommended setting determination unit determines a recommended setting for the camera on the basis of a correspondence relationship between the score and the camera setting. The camera control unit controls the camera on the basis of the recommended setting.

A technique for reducing a work load during introduction of a system in the system processing an image generated by a camera. An information processing apparatus includes at least an accumulation unit, a recommended setting determination unit, and a camera control unit. The accumulation unit accumulates a score obtained through an authentication process using an image in which a person is captured and a camera setting at which a camera generates the image in a storage area. The recommended setting determination unit determines a recommended setting for the camera on the basis of a correspondence relationship between the score and the camera setting. The camera control unit controls the camera on the basis of the recommended setting.

An example method includes determining, by a controller of an image capture system, a plurality of sets of exposure parameter values for one or more exposure parameters. The plurality of sets of exposure parameter values are determined at an exposure determination rate. The method further includes capturing, by an image capture device of the image capture system, a plurality of images. Each image of the plurality of images is captured according to a set of exposure parameter values of the plurality of sets of exposure parameter values. The method also includes sending, by the controller of the image capture system to an image processing unit, a subset of the plurality of images. Each subset of images is sent at a sampling rate, and the sampling rate is less than the exposure determination rate.

There is provided a notifying apparatus. A detecting unit detects a motion amount of an object from an image obtained through first shooting, the first shooting being carried out repeatedly at predetermined intervals of time. A converting unit converts the motion amount into a motion blur amount that will arise in second shooting, on the basis of the predetermined intervals of time and an exposure time used in the second shooting. A notifying unit makes a notification of motion blur on the basis of the motion blur amount. The notifying unit changes a form of the notification in accordance with a magnitude of the motion blur amount.

An imaging element incorporates a reading portion that reads out captured image data at a first frame rate, a storage portion that stores the image data, a processing portion that processes the image data, and an output portion that outputs the processed image data at a second frame rate lower than the first frame rate. The reading portion reads out the image data of each of a plurality of frames in parallel. The storage portion stores, in parallel, each image data read out in parallel by the reading portion. The processing portion performs generation processing of generating output image data of one frame using the image data of each of the plurality of frames stored in the storage portion.

Wireless chargers for cameras include a body, a power circuit in the body, a charging coil connected to the body, the charging coil electrically connected to the power circuit, and the charging coil operable to generate a current in response to positioning adjacent to the wireless charger. The body may include a lens mount configured to receive interchangeable lenses, and the charging coil may be on a body surface opposite the lens mount. The body may include a display, and the charging coil may underly the display. The charging coil may be registered with a periphery of the display. The body may have a forward side including a lens, and a rear side including a display, and the charging coil may be proximate the rear side.

Wireless chargers for cameras include a body, a power circuit in the body, a charging coil connected to the body, the charging coil electrically connected to the power circuit, and the charging coil operable to generate a current in response to positioning adjacent to the wireless charger. The body may include a lens mount configured to receive interchangeable lenses, and the charging coil may be on a body surface opposite the lens mount. The body may include a display, and the charging coil may underly the display. The charging coil may be registered with a periphery of the display. The body may have a forward side including a lens, and a rear side including a display, and the charging coil may be proximate the rear side.

The present disclosure relates to navigation and to systems and methods for using a dual sensor readout channel to allow for frequency detection. In one implementation, at least one processing device may receive a plurality of images acquired by a camera onboard a host vehicle, wherein the plurality of images are received via a first channel and via a second channel, and wherein the first channel is associated with a first frame capture rate, and the second channel is associated with a second frame capture rate different from the first frame capture rate. The processing device may use images received via the first channel to detect flickering and non-flickering light sources in an environment of the host vehicle; and provide, based on images received via the second channel, images for showing on one or more human-viewable displays.

A user interface to a virtual camera for a 3-D rendering application provides various features. A rendering engine can continuously refine the image being displayed through the virtual camera, and the user interface can contain an element for indicating capture of the image as currently displayed, which causes saving of the currently displayed image. Autofocus (AF) and autoexposure (AE) reticles can allow selection of objects in a 3-D scene, from which an image will be rendered, for each of AE and AF. A focal distance can be determined by identifying a 3-D object visible at a pixel overlapped by the AF reticle, and a current viewpoint. The AF reticle can be hidden in response to a depth of field selector being set to infinite depth of field. The AF and AE reticles can be linked and unlinked, allowing different 3-D objects for each of AF and AE.

An image pickup device includes first and second cameras, and first and second image signal processors (ISP). The first camera obtains a first image of an object. The second camera obtains a second image of the object. The first ISP performs a first auto focusing (AF), a first auto white balancing (AWB) and a first auto exposing (AE) for the first camera based on a first region-of-interest (ROI) in the first image, and obtains a first distance between the object and the first camera based on a result of the first AF. The second ISP calculates first disparity information associated with the first and second images based on the first distance, moves a second ROI in the second image based on the first disparity information, and performs a second AF, a second AWB and a second AE for the second camera based on the moved second ROI.