An image processing method, a camera assembly and a mobile terminal. The image processing method includes: obtaining a Bayer image and a panchromatic image, obtaining an RGB image after processing the Bayer image with a first processing algorithm and a demosaicing algorithm, obtaining a luminance image after processing the panchromatic image with the first processing algorithm, obtaining a fused RGB image by fusing the RGB image and the luminance image, and obtaining a YUV image after processing the fused RGB image with a second processing algorithm.

An image processing method, a camera assembly and a mobile terminal. The image processing method includes: obtaining a Bayer image and a panchromatic image, obtaining an RGB image after processing the Bayer image with a first processing algorithm and a demosaicing algorithm, obtaining a luminance image after processing the panchromatic image with the first processing algorithm, obtaining a fused RGB image by fusing the RGB image and the luminance image, and obtaining a YUV image after processing the fused RGB image with a second processing algorithm.

A solid-state imaging element synthesizes luminance signals and chrominance signals to obtain an image. The solid-state imaging element includes a plurality of first pixels and a plurality of second pixels. Each of the plurality of second pixels has a spectral response characteristic in white. The solid-state imaging element generates the chrominance signals, using output signals from the plurality of first pixels. The solid-state imaging element generates the luminance signals, using output signals from the plurality of second pixels, without using the output signals from the plurality of first pixels.

A solid-state imaging element synthesizes luminance signals and chrominance signals to obtain an image. The solid-state imaging element includes a plurality of first pixels and a plurality of second pixels. Each of the plurality of second pixels has a spectral response characteristic in white. The solid-state imaging element generates the chrominance signals, using output signals from the plurality of first pixels. The solid-state imaging element generates the luminance signals, using output signals from the plurality of second pixels, without using the output signals from the plurality of first pixels.

An imaging apparatus including an imaging lens, and an image sensor array of first and second image sensor units, wherein a single first image sensor unit includes a single first microlens and a plurality of image sensors, a single second image sensor unit includes a single second microlens and a single image sensor, light passing through the imaging lens and reaching each first image sensor unit passes through the first microlens and forms an image on the image sensors constituting the first image sensor unit, light passing through the imaging lens and reaching each second image sensor unit passes through the second microlens and forms an image on the image sensor constituting the second image sensor unit, an inter-unit light shielding layer is formed between the image sensor units, and a light shielding layer is not formed between the image sensor units constituting the first image sensor unit.

An image processing method, a camera assembly, and a mobile terminal. The image processing method includes: obtaining a full-size image in a first operation mode; obtaining a first YUV image by processing the full-size image with an image processing pipeline; obtaining a color image and a panchromatic image in a second operation mode; and obtaining a second YUV image by processing the color image and the panchromatic image with the image processing pipeline.

An image processing method, a camera assembly, and a mobile terminal. The image processing method includes: obtaining a full-size image in a first operation mode; obtaining a first YUV image by processing the full-size image with an image processing pipeline; obtaining a color image and a panchromatic image in a second operation mode; and obtaining a second YUV image by processing the color image and the panchromatic image with the image processing pipeline.

A display device includes a substrate and an active pattern positioned above the substrate and including a plurality of channel regions and a plurality of conductive regions. The display device includes a plurality of scan lines extending substantially in a first direction. The display device includes a data line and a driving voltage line crossing the plurality of scan lines. The display device includes a first transistor including a first channel region among the plurality of channel regions and a first gate electrode. The display device includes a first connector electrically connecting the first gate electrode of the first transistor and a first conductive region among the plurality of conductive regions to each other. The driving voltage line overlaps at least a portion of the first connector along a direction orthogonal to an upper surface of the substrate.

A vehicular interior rearview mirror assembly includes a mirror head accommodating an interior mirror reflective element. The mirror reflective element has a mirror transflector that transmits near infrared light incident thereon, transmits visible light incident thereon and reflects visible light incident thereon. A camera is disposed within the mirror head and views through the mirror transflector. The camera includes an imaging sensor having a quantum efficiency (QE) of at least 15% for near infrared light having a wavelength of 940 nm. First, second and third near infrared illumination sources are disposed within the mirror head and operable to emit near infrared light that passes through the mirror transflector. The near infrared illumination sources are at respective locations at the mirror reflective element and, when powered, illuminate respective seat regions for a driver-monitoring function or an occupant-detection function.

A vehicular interior rearview mirror assembly includes a mirror head accommodating an interior mirror reflective element. The mirror reflective element has a mirror transflector that transmits near infrared light incident thereon, transmits visible light incident thereon and reflects visible light incident thereon. A camera is disposed within the mirror head and views through the mirror transflector. The camera includes an imaging sensor having a quantum efficiency (QE) of at least 15% for near infrared light having a wavelength of 940 nm. First, second and third near infrared illumination sources are disposed within the mirror head and operable to emit near infrared light that passes through the mirror transflector. The near infrared illumination sources are at respective locations at the mirror reflective element and, when powered, illuminate respective seat regions for a driver-monitoring function or an occupant-detection function.