An electronic device comprises a light-emitting information receiving circuit and a color correction processing circuit. The light-emitting information receiving circuit is configured to be electrically connected to a color correction detection device to receive light-emitting information of an external flash detected by the color correction detection device. The color correction processing circuit is electrically connected to the light-emitting information receiving circuit to perform color correction processing according to the light-emitting information so as to generate color correction result information, the color correction result information being configured to be transmitted to the external flash to correct the light emission of the external flash. Moreover, provided is a color correction system of the external flash.

A vehicular vision system includes a camera module configured for mounting at an in-cabin portion of a windshield of a vehicle and including a circuit board and a camera that views forward of the vehicle and through the windshield. The camera includes a CMOS imaging sensor array. A data processor is operable to process image data captured by the CMOS imaging sensor array. Image data captured by the CMOS imaging sensor array is encoded by a data encoder chip. Image data captured by the CMOS imaging sensor array that is encoded at the data encoder chip is carried as a data stream from the camera module to the data processor via a cable. Communication via the cable between the camera and the data processor is bidirectional. The data processor is located in the vehicle remote from the camera module.

A traffic monitoring terminal and a traffic monitoring system are provided. The traffic monitoring terminal includes a camera module configured to acquire a traffic image of an intersection and a control module configured to acquire a number of vehicles waiting at the intersection based on the traffic image.

A traffic monitoring terminal and a traffic monitoring system are provided. The traffic monitoring terminal includes a camera module configured to acquire a traffic image of an intersection and a control module configured to acquire a number of vehicles waiting at the intersection based on the traffic image.

Embodiments of the present disclosure provide a system for controlling a camera component, the camera component is applicable for an electronic device, and the system may include a first processing unit and a target processing unit. The target processing unit is configured to control the camera component. The first processing unit is configured to determine whether the target processing unit writes data to the first processing unit in accordance with a preset time interval, and when the target processing unit does not write data to the first processing unit over the preset time interval, change an operating state of the camera component and/or control the electronic device to restart.

An observation and designation apparatus includes a first image sensor and a second image sensor that are connected to an electronic image processor circuit connected to a display. The first image sensor and the second image sensor provide fields that are superposed to supply respectively at least a first image and a second image of the same scene. The appliance further includes a laser emitter for emitting a laser beam lying in a predetermined range of wavelengths into a predetermined zone of the field of the second sensor; a region-of-interest filter extending in front of the second sensor. The electronic processor circuit superposes the two images by using the zone of the second image that corresponds to the third region of the filter to register the second image spatially relative to the first image. An observation and designation method makes use of such filtering.

The present technology relates to a display device and a display control method that enable improvement of user experience. Provided is a display device including: a control unit that, when displaying a video corresponding to an image frame obtained by capturing a user on a display unit, controls luminance of a lighting region including a first region including the user in the image frame and at least a part of a second region of the second region excluding the first region to cause the lighting region to function as a light that emits light to the user. The present technology can be applied, for example, to a television receiver.

Disclosed is an object recognition method including: obtaining a first RGB image by using a camera; predicting at least one first region, in which an object is unrecognizable, in the first RGB image based on brightness information of the first RGB image; determining at least one second region, in which an object exists, from among the at least one first region, based on object information obtained through a dynamic vision sensor; obtaining an enhanced second RGB image by controlling photographic configuration information of the camera in relation to the at least one second region; and recognizing the object in the second RGB image.

This invention enables one to check flicker of a HFR image signal. A display image signal of a first frame rate for flicker check is obtained on the basis of an image signal of a second frame rate. For example, the display image signal of the first frame rate is generated from the image signal of the second frame rate by a frame thinning process. In this case, a frame to be thinned is determined from a relationship between the second frame rate and a light source frequency. For example, the number of frames to be a flicker period is obtained from the second frame rate and the light source frequency, and the frame to be thinned is determined so that continuous frames of the number of frames to be the flicker period are present.

Systems and methods to proactively adapt image sensor settings of an occupant monitoring system to accommodate ambient lighting changes are provided. The system may track current ambient light, track the driver, and predict upcoming changing lighting conditions. Sensors are used to predict when the ambient light will change and preemptively adjust to prevent dark or washout images. The sensor adjustment may be timed so that the adjustment is made just in time or concurrently with the change in ambient light conditions. The system may predict when the light on the occupant's face will change and proactively readjust the settings of the sensor to accommodate the changed lighting conditions.