A light emitting unit emits infrared rays. An imaging element converts incident infrared rays into an electric signal and outputs the electric signal. A control unit estimates a light emission timing at which infrared rays are emitted from another infrared imaging device based on an infrared picture generated based on the electrical signal output from the imaging element, and performs control to cause the light emitting unit to emit infrared rays in a period in which the infrared rays are not emitted from the another infrared imaging device.

A method of adjusting brightness of a foreground video displayed over a background in a user device is provided. The method includes determining enhancement factors for background sections in a background frame of the background, determining an enhancement mask for each foreground sub-frame of the foreground video based on enhancement factor of corresponding background section and determining enhanced brightness values for each foreground pixel in the foreground video based on the enhancement mask. The method of the disclosure provides real-time, clear and distinct viewing of an enhanced foreground video in varying brightness conditions of the background sections.

According to certain embodiments, an electronic device comprises a display; a camera disposed under the display; and a processor configured to, obtain a first image using the camera in a first state in which a first portion of the display corresponding to a position where the camera is disposed is in a first mode, obtain a second image, using the camera in a second state in which the first portion of the display is in a second mode, calculate correction values, based on first data for a first area of the first image and second data for a second area of the second image, wherein the second area of the second image corresponds to the first area of the first image, and correct at least one image among a plurality of images, using the correction values, wherein one of obtaining the first image and obtaining the second image is responsive to the other of obtaining the first image and the second image.

According to certain embodiments, an electronic device comprises a display; a camera disposed under the display; and a processor configured to, obtain a first image using the camera in a first state in which a first portion of the display corresponding to a position where the camera is disposed is in a first mode, obtain a second image, using the camera in a second state in which the first portion of the display is in a second mode, calculate correction values, based on first data for a first area of the first image and second data for a second area of the second image, wherein the second area of the second image corresponds to the first area of the first image, and correct at least one image among a plurality of images, using the correction values, wherein one of obtaining the first image and obtaining the second image is responsive to the other of obtaining the first image and the second image.

Systems and methods for generating and processing images captured while inspecting above-ground pipelines are disclosed. Embodiments may include a robotic crawler or other devices which carry imaging equipment and traverse a target pipe which are configured to capture image data simultaneously from a plurality of angles. Such systems may substantially reduce and in some cases overcome the need to take multiple traversals of a pipeline under inspection. Embodiments may also be directed toward control systems for such devices as well as image processing systems which process the multiple image sets to produce a composite imaging result.

Systems and methods for generating and processing images captured while inspecting above-ground pipelines are disclosed. Embodiments may include a robotic crawler or other devices which carry imaging equipment and traverse a target pipe which are configured to capture image data simultaneously from a plurality of angles. Such systems may substantially reduce and in some cases overcome the need to take multiple traversals of a pipeline under inspection. Embodiments may also be directed toward control systems for such devices as well as image processing systems which process the multiple image sets to produce a composite imaging result.

Automatic exposure control of an in-vehicle camera is performed under dark driving environments such as at night. An in-vehicle camera system includes a vehicle camera mounted in a vehicle configured to capture surroundings of the vehicle, and control circuitry that controls an exposure level of an image captured by the vehicle camera, the control of the exposure level being based on brightness information of a detection area set within the image, the detection area being a portion of the captured image and configured to output the image having exposure control performed thereon to a display.

Provided is an imaging device including: an imaging unit (130) that generates a one frame image by sequentially receiving each reflected light reflected by a subject by intermittently and sequentially irradiating the subject with each irradiation light having a different wavelength according to a position of the moving subject, temporarily and sequentially holding signal information based on the reflected light of each wavelength, and collectively reading the held signal information; and a combining unit (140) that generates a combined image by cutting a subject image corresponding to the reflected light of each wavelength from the one frame image and superimposing a plurality of the cut subject images.

According to certain embodiments, an electronic device comprises a display; a camera disposed under the display; and a processor configured to, obtain a first image using the camera in a first state in which a first portion of the display corresponding to a position where the camera is disposed is in a first mode, obtain a second image, using the camera in a second state in which the first portion of the display is in a second mode, calculate correction values, based on first data for a first area of the first image and second data for a second area of the second image, wherein the second area of the second image corresponds to the first area of the first image, and correct at least one image among a plurality of images, using the correction values, wherein one of obtaining the first image and obtaining the second image is responsive to the other of obtaining the first image and the second image.

According to certain embodiments, an electronic device comprises a display; a camera disposed under the display; and a processor configured to, obtain a first image using the camera in a first state in which a first portion of the display corresponding to a position where the camera is disposed is in a first mode, obtain a second image, using the camera in a second state in which the first portion of the display is in a second mode, calculate correction values, based on first data for a first area of the first image and second data for a second area of the second image, wherein the second area of the second image corresponds to the first area of the first image, and correct at least one image among a plurality of images, using the correction values, wherein one of obtaining the first image and obtaining the second image is responsive to the other of obtaining the first image and the second image.