A camera assembly can include a housing that includes a front side that includes a front side perimeter, a back side that includes a back side perimeter, and a surface that extends between the front side and the back side; a camera that includes a front side aperture; a front side illumination light; and a status light.

Embodiments relate to the field of intelligent vehicles, and may be applied to vehicle to everything. A method for controlling an operation of a vehicle-mounted camera based on computer vision, a device, and a system are provided. The method is implemented by a mobile device, and the method includes: communicatively connecting a vehicle control apparatus, where the vehicle control apparatus includes at least one vehicle-mounted camera; configuring at least one virtual camera based on camera information, where the at least one virtual camera corresponds to the at least one vehicle-mounted camera in a one-to-one manner; and enabling the at least one virtual camera to obtain a video signal shot by a vehicle-mounted camera corresponding to the at least one virtual camera. A passenger can control an operation on the vehicle-mounted camera, which brings good user experience. The method may be applied to an artificial intelligence device.

A system includes a processor and a non-transitory computer-readable medium containing instructions that when executed by the processor causes the processor to perform operations comprising displaying a prompt to a user of a mobile device on a display of a mobile device to capture an image representing at least a portion of a mouth of the user using a rear-facing camera of the mobile device, where the rear-facing camera is on an opposite side of the mobile device including the display. The operations further comprise controlling the rear-facing camera to enable the rear-facing camera to capture the image, receiving the image, and outputting, user feedback based on the image, where the user feedback is outputted on the display that is on the opposite side of the mobile device than the rear-facing camera.

An imaging apparatus includes an imaging unit, an operation unit configured to be operated by an operation in a first phase and an operation in a second phase, a recording control unit configured to record a moving image captured by the imaging unit in a moving image file in response to an operation performed on the operation unit, and a control unit configured to perform control to cause the imaging apparatus to display file information about the moving image file to be recorded by the recording control unit in response to performance of the operation in the first phase, and to cause the imaging apparatus to hide the file information that is displayed in response to the performance of the operation in the first phase, in response to performance of the operation in the second phase.

Various implementations disclosed herein include devices, systems, and methods that generates a three-dimensional (3D) model based on a selected subset of the images and depth data corresponding to each of the images of the subset. For example, an example process may include acquiring sensor data during movement of the device in a physical environment including an object, the sensor data including images of a physical environment captured via a camera on the device, selecting a subset of the images based on assessing the images with respect to motion-based defects based on device motion and depth data, and generating a 3D model of the object based on the selected subset of the images and depth data corresponding to each of the images of the selected subset.

An image capturing apparatus that allows a photographer to easily recognize whether or not a blurring generated in an image at the time of image capturing is due to a spherical aberration variable mechanism is provided. The image capturing apparatus, to/from which a lens barrel can be attached/detached, comprising a mounting unit configured to mount the lens barrel, a processor; and a memory storing a program which, when executed by the processor, causes the image capturing apparatus to obtain an adjustment amount of spherical aberration from the lens barrel mounted on the mounting unit, and control a display device to display information about the adjustment amount together with an image obtained through the lens barrel.

The invention provides a system and a computer-implemented method for generating and editing a video including providing a mobile communication device comprising a camera, a display, a central processing unit (CPU), a video generating application and a memory. Next, starting the video generating application, and then opening the camera and providing camera tutorials. The camera tutorials comprise instructions for camera positioning, camera moving, and camera aligning while taking videos. Next, taking videos of a scene following the instructions for camera positioning, camera moving, and camera aligning while taking videos. Next, uploading the videos to the memory, editing the videos and producing a composite video for the scene. The camera tutorials include a “moving forward/backward” tutorial directing a user first to hold the camera still, to align a horizontal view line in the display with a marker line, and then to move the user's body forward or backward while taking a video of the scene. The editing of the videos includes slowing the videos down, and matching rhythm of music accompanying each video to transitions of consecutive videos. The slowing down of the videos includes removing every other frame.

In some examples, an unmanned aerial vehicle (UAV) employs one or more image sensors to capture images of a scan target and may use distance information from the images for determining respective locations in three-dimensional (3D) space of a plurality of points of a 3D model representative of a surface of the scan target. The UAV may compare a first image with a second image to determine a difference between a current frame of reference position for the UAV and an estimate of an actual frame of reference position for the UAV. Further, based at least on the difference, the UAV may determine, while the UAV is in flight, an update to the 3D model including at least one of an updated location of at least one point in the 3D model, or a location of a new point in the 3D model.

An imaging apparatus includes: a display unit configured to display on a display a live image of a subject and previously captured images; an image capturing unit configured to capture an image of the subject; and a recording unit configured to record in a recording medium the captured image of the subject which has been captured by the image capturing unit and the previously captured images in association with disposition information which includes a display position of the captured image of the subject and display positions of the previously captured images.

The present invention relates to a new universal control interface for cameras and other audio-visual recording/using instruments, and more specifically a multi-axis visual interface for simultaneous display and control of aperture (Av), shutter speed (Tv), ISO, and/or other parameters like exposure value (EV). The invention relates to either a triangular, rectangle or clover shape interface where the parameters are visually represented on one of the axis, side or branch of the interface and where the user instead of altering the parameters, will provide intention such as (a) depth-of field, (b) motion blur, (c) granularity, or the composite (d) exposure. The invention further describes how in some cases, one or more of these parameters can be locked or not available based on the technology used for the delay and control interface.