The present technology relates to an imaging device capable of selectively taking out only a specific electromagnetic wavelength and generating a signal with an enhanced wavelength resolution, and an electronic apparatus. There are provided a first pixel including a metallic thin film filter configured to transmit a light in a first frequency band and a second pixel including a color filter configured to transmit a light in a second frequency band wider than the first frequency band. A signal in a third frequency band is generated from the respective signals of a plurality of first pixels each including a metallic thin film filter configured to transmit a light in the different first frequency bands. The present technology can be applied to a CMOS image sensor of backside irradiation type or surface irradiation type, for example.

Embodiments of the invention provide an image sensor image sensor including an image sensor structure. The image sensor structure includes a multitude of image elements arranged in a grid-shaped manner in a first direction and in a second direction orthogonal to the first direction. An image element of the multitude of image elements includes a plurality of filter elements spatially arranged side by side. The plurality of filter elements includes at least one color filter and at least one additional filter from a filter group. The filter group includes a first absorption filter with a first optical bandwidth, a second absorption filter with a second optical bandwidth different from the first optical bandwidth, a first polarization filter with a first polarization characteristic, a second polarization filter with a second polarization characteristic different from the first polarization characteristic, and a filter element without absorption effect or polarization effect.

The present disclosure relates to an image processing method and device, a camera component, an electronic device, and a storage medium. The component includes a first camera module sensing first-band light to generate a first image, a second camera module sensing the first-band light and second-band light and generating a second image, an infrared light source emitting the second-band light and a processor. The second image includes a bayer subimage and an infrared subimage. The processor is coupled with the first camera module, the second camera module and the infrared light source respectively. The processor is configured to perform image processing on at least one of the bayer subimage or the infrared subimage and the first image. In the embodiments, a depth image may be acquired without arranging any depth camera in a camera module array, so that the size of the camera component may be reduced, a space occupied by the component in an electronic device may be reduced, and miniaturization and cost reduction of the electronic device are facilitated.

A solid-state imaging device capable of acquiring an RGB image, a CMY image, and luminance information through one imaging process. The solid-state imaging device includes a pixel array portion in which a plurality of pixel unit groups are arrayed, the pixel unit group including pixel units disposed in a 2×2 matrix, the pixel unit including pixels disposed in an 2×2 matrix, and the pixels including a photoelectric conversion unit and a color filter. Each of the pixel unit groups is configured such that an R filter and a C filter are included as the color filters in a first pixel unit among four pixel units constituting the pixel unit group, a G filter and an M filter are included as the color filters in each of second and third pixel units, and a B filter and a Y filter are included as the color filters in a fourth pixel unit.

A method of calibrating an image sensor including a color filter array having a first-type array pattern, the method includes capturing a target using the image sensor to generate first image data, performing a white balance operation on the first image data to generate second image data, performing an inverse white balance operation on the second image data based on a second-type array pattern to generate third image data, the second-type array pattern being different from the first-type array pattern, and calibrating the image sensor based on the third image data.

An electronic device includes one or more processors and memory storing instructions for execution by the one or more processors. The stored instructions include instructions for: receiving infrared image information for a three-dimensional area; receiving non-infrared image information for the same three-dimensional area; performing nonlinear intensity adjustment for the received infrared image information; performing nonlinear intensity adjustment for the received non-infrared image information; blending the intensity-adjusted infrared image information and the intensity-adjusted non-infrared image information to obtain a merged image information; and providing the merged image information for determining a depth map. Also disclosed are a corresponding method performed by the electronic device and a computer readable storage medium storing instructions for execution by one or more processors of an electronic device.

The present technology relates to an imaging device, an imaging method, and an electronic device enabling to improve image quality.

Two or more imaging units capable of imaging or sensing a same subject are included, in which at least one first imaging unit among the two or more imaging units includes a first filter configured to transmit a plurality of wavelength bands, and at least another one second imaging unit other than the first imaging unit among the two or more imaging units includes a second filter capable of varying a wavelength band. The present technology can be applied to, for example, a compound-eye camera module, an imaging device including a compound-eye camera module, a device that includes an imaging device and provides virtual reality or the like.

An optical sensor device, includes an optical sensor that has a set of sensor elements, an optical filter that includes a plurality of regions, and one or more processors. A region, of the plurality of regions, includes a first set of optical channels comprising optical channels that are configured to pass light associated with respective subranges of a first wavelength range, a second set of optical channels comprising optical channels that are configured to pass light associated with respective subranges of a second wavelength range, and a third set of optical channels comprising optical channels that are configured to pass light associated with respective subranges of a third wavelength range. The one or more processors are configured to obtain, from the optical sensor, sensor data associated with a scene and determine image information associated with the scene based on the spectral information.

To satisfactorily transmit uncompressed RAW data between devices. A transmission unit transmits uncompressed RAW data to an external device via an HDMI transmission path. For example, the uncompressed RAW data is uncompressed RAW data in a Bayer layout. Furthermore, for example, the bit depth of each pixel of the uncompressed RAW data is 16 bits, and the transmission unit transmits the uncompressed RAW data using the YC 12 bit transfer mode. For example, the transmission unit transmits metadata related to the uncompressed RAW data together with the uncompressed RAW data.

An image sensor (10), a camera assembly (40) and a mobile terminal (90) are disclosed. The image sensor (10) comprises panchromatic pixels and color pixels. The color pixels have the spectral response narrower than that of the panchromatic pixels, and the panchromatic pixels have the full-well capacity greater than that of the color pixels.