Disclosed is an electronic apparatus comprising: a camera module; a communication module; and a processor electrically connected to the camera module and the communication module, wherein the processor is capable of: obtaining an image of one or more external objects by using the camera module; recognizing at least one specified external object among the one or more external objects; transmitting image color information, corresponding to said at least one recognized specified external object, to an external electronic apparatus via the communication module; receiving attribute information on a light source for the image, determined using reference color information, corresponding to said at least one specified external object, and the image color information, from the external electronic apparatus; and correcting the color temperature of the image by using the attribute information received from the external electronic apparatus. Other various embodiments identified in the description are possible.

An image capturing device with automatic white balance and an automatic white balance correction method are provided. The image capturing device includes a lens assembly, a light diffuser, an image sensor and a processor. The relative position of the light diffuser and the lens assembly is fixed. The processor is electrically connected to the image sensor having a first sensing region and a second sensing region. The light diffuser converts a fraction of the incident light to the reference light. The first sensing region converts the incident light to the display image information. The second sensing region converts the reference light to the correction information. The processor determines a reference gain average according to at least one color gain of the correction information and obtains at least one color gain correction value according to the reference gain average to adjust the white balance setting of the display image information.

The present disclosure relates to a photographing system and a method for synchronizing image quality thereof, and more particularly, to a photographing system capable of synchronizing image quality between a plurality of cameras by controlling the image quality of a sub camera by transmitting, together with a synchronization signal, an image quality adjustment value generated by the main camera to the sub camera and a method for synchronizing the image quality.

An imaging system includes a primary imager and plurality of 3A-control sensors. The primary imager has a first field of view and includes a primary image sensor and a primary imaging lens with a first optical axis. The primary image sensor has a primary pixel array and control circuitry communicatively coupled thereto. The plurality of 3A-control sensors includes at least one of a peripheral imager and a 3A-control sensor. The peripheral imager, if included, has a second field of view including (i) at least part of the first field of view and (ii) a phase-difference auto-focus (PDAF) sensor and a peripheral imaging lens, the PDAF sensor being separate from the primary image sensor. The 3A-control sensor, if included, is separate from the primary pixel array and communicatively connected to the control circuitry to provide one of auto-white balance and exposure control for the primary pixel array.

A method for operating a camera system of a motor vehicle, in which images of an environmental region of the motor vehicle are captured by means of an image sensor of the camera system via an optic device and an image correction function is activated by means of a control unit of the camera system, in which a light fall-off in a boundary region of the images caused by the optic device is compensated for, wherein a current brightness level of the environmental region is captured by means of the control unit and the activation and deactivation of the image correction function are effected depending on the current brightness level.

Techniques related to improved front facing camera performance using display light during exposure of a scene are discussed. Such techniques may include providing, via a display device, exposure light during exposure of the scene such that providing the exposure light includes setting regions of the display device to different colors during exposure.

A method for processing high dynamic range data from a nonlinear camera includes; generating an input image comprising a plurality of pixels, each pixel having an initial pixel value, wherein the initial pixel values are generated using a camera transition curve; generating a first lookup table representing a combination of an inverse function and a re-compression function, the first lookup table having input values and output values, wherein each input value is linked to one output value, the inverse function is the inverse of the camera transition curve, the re-compression function is a smooth and continuous function having a slope at each input value which is greater than or equal to a corresponding slope of the camera transition curve, the first lookup table is generated such that the inverse function precedes the re-compression function; and generating a first image by converting the initial pixel values using the first lookup table.

An image photographing apparatus includes an image sensor and a processor. The image sensor is configured to photograph at least one image of an object. The processor is configured to: obtain an image of the object under a preset light source based on the at least one image; for the image of the object under the preset light source, calculate a difference between sub-images of filter points at same corresponding positions in any two filter arrays in a first filter array set, to obtain a plurality of narrowband spectrum responses of the first filter array set; and obtain spectrum information of the object in the first filter array set based on the plurality of narrowband spectrum responses.

Introduced here are computer programs and associated computer-implemented techniques for achieving high-fidelity color reproduction in the absence of any known reflectance spectrums. That is, high-fidelity color reproduction can be achieved without portable references, such as gray cards and color checkers. To accomplish this, a new reference spectrum—the “reference illuminant spectrum”—is introduced into scenes to be imaged by image sensors. The reference illuminant spectrum is created by a multi-channel light source whose spectral properties are known.

A multi-function imaging system comprises a light sensor and a software defined light source to enable real-time automatic adjustment of various parameters of the one or more light sources. The system is realized in a single unit, or as multiple co-located units, thus reducing the cost of having such multiple functions. The system is capable of self-calibrating in the field to enable accurate imaging.