An image acquisition apparatus includes a first image sensor configured to obtain a first image based on detection of a light of a first wavelength band; a second image sensor configured to obtain a second image based on detection of a light of a second wavelength band that is wider than the first wavelength band; and a processor configured to obtain a third image having a spatial resolution corresponding to the first image and a color gamut corresponding to the second image based on the first image and the second image. The image acquisition apparatus may provide an image with a high spatial resolution and a wide color gamut.

Provided is an imaging device (1) capable of improving quality of an image captured using a color filter. An imaging device according to an embodiment includes a pixel array (110) including a plurality of pixel blocks (130) each including 6×6 pixels, and each pixel block includes a first pixel on which a first optical filter that transmits light in a first wavelength range is provided, a second pixel on which a second optical filter that transmits light in a second wavelength range is provided, a third pixel on which a third optical filter that transmits light in a third wavelength range is provided, and a fourth pixel on which a fourth optical filter that transmits light in a fourth wavelength range is provided. The first pixels are alternately arranged in each of a row direction and a column direction of the arrangement, one second pixel, one third pixel, and one fourth pixels are alternately arranged in each row and each column of the arrangement, and the pixel block further includes a line including at least one second pixel, one third pixel, and one fourth pixel in a first oblique direction that is parallel to a diagonal of the pixel block of the arrangement, and a line including at least one second pixel, one third pixel, and one fourth pixel in a second oblique direction that is parallel to a diagonal of the pixel block and is different from the first oblique direction.

An imaging apparatus includes an image sensor, a filter array disposed on an optical path from a target object to the image sensor and including two-dimensionally-arranged optical filters, and a processing circuit that generates at least four pieces of spectral image data based on an image acquired by the image sensor. The optical filters include various types of optical filters with different spectral transmittance. Each of the at least four pieces of spectral image data indicates an image corresponding to one of at least four wavelength bands. The filter array includes at least one characteristic section. The processing circuit detects a relative position between the filter array and the image sensor based on the at least one characteristic section in the image acquired by the image sensor, and compensates for deviation between the relative position and a preliminarily-set relative position when the processing circuit detects the deviation.

An image sensor includes multiple photoelectric conversion elements and multiple individual color filters to generate multiple colors. The multiple individual color filters are arranged corresponding to the multiple photoelectric conversion elements, respectively. At least one of the multiple individual color filters includes a primary color type individual color filter. The primary color type individual color filter allows light of a corresponding primary color to permeate. The primary color type individual color filter has a first given transmittance for one of other primary colors other than the corresponding primary color, at which one of the other primary colors permeates the primary color type individual color filter. The first given transmittance is higher than a lower limit of a transmittance improving a sensitivity of the image sensor.

A method of reducing noise in an input image by setting, as a local window among color pixels included in the input image, a target pixel and neighboring pixels adjacent to the target pixel, determining color pixel values for the target pixel and each of the neighboring pixels included in the local window, generating local color average values are generated by averaging, color by color, the color pixel values, generating offset color pixel values by converting the color pixel values of the target pixel and the neighboring pixels based on the local color average values, and generating a compensated color pixel value of the target pixel by adjusting the color pixel value of the target pixel based on the offset color pixel values.

In some aspects, a device may receive, from a pixel array of a camera, a first image. The device may configure, based at least in part on the first image, a setting of a filter. The filter may be included within a filter array that is arranged within the camera in association with the pixel array. The device may cause the pixel array to capture a second image. Numerous other aspects are described.

A solid state imaging device includes a pixel array unit in which color filters of a plurality of colors are arrayed with four pixels of vertical 2 pixels×horizontal 2 pixels as a same color unit that receives light of the same color, shared pixel transistors that are commonly used by a plurality of pixels are intensively arranged in one predetermined pixel in a unit of sharing, and a color of the color filter of a pixel where the shared pixel transistors are intensively arranged is a predetermined color among the plurality of colors. The present technology can be applied, for example, to a solid state imaging device such as a back-surface irradiation type CMOS image sensor.

Provided is an image acquisition apparatus including an image sensor configured to obtain an image, and a processor configured to obtain a basis based on a surrounding environment of the image acquisition apparatus, estimate illumination information based on the obtained basis, and perform color conversion on the image based on the estimated illumination information.

Provided are a spectral filter, and an image sensor and an electronic device including the spectral filter. The spectral filter includes: a first metal reflective layer; a second metal reflective layer provided above the first metal reflective layer; a plurality of cavities provided between the first and second metal reflective layers, the plurality of cavities including first patterns corresponding to different center wavelengths; and a plurality of lower pattern films provided below the first metal reflective layers, the plurality of lower pattern films including second patterns corresponding to the different center wavelengths.

Disclosed is an image sensing device including a pixel array, wherein the pixel array includes a first sub-pixel array including pixels each having a green filter and disposed in a first diagonal direction, and pixels each having a white filter and disposed in a second diagonal direction, a second sub-pixel array including pixels each having the green filter and disposed in the first diagonal direction, and pixels each having the white filter and disposed in the second diagonal direction, a third sub-pixel array including pixels each having a red filter and disposed in the second diagonal direction, and pixels each having the white filter and disposed in the first diagonal direction, and a fourth sub-pixel array including pixels each having a blue filter and disposed in the second diagonal direction, and pixels each having the white filter and disposed in the first diagonal direction.