Metasurfaces and systems including metasurfaces for imaging and methods of imaging are described. Such metasurfaces may be formed on a substrate from a plurality of posts. The metasurfaces are configured to be optically active over a wavelength range and in certain embodiments are configured to form lenses. In particular, the metasufaces described herein may be configured to focus light passed through the metasurface in an extended depth of focus. Accordingly, the disclosed metasurfaces are generally suitable for generating color without or with minimal chromatic aberrations, for example, in conjunction with computational reconstruction.

A method includes capturing, with an image capture device, a first image of a scene while a portion of the scene has a first alignment with a first detector of a focal plane array and a first bandpass filter is between the portion of the scene and the first detector. The method includes, in response to determining that the portion of the scene has a second alignment with a second detector of the focal plane array, the second alignment substantially matching the first alignment, and that a second bandpass filter having a second frequency range that is distinct from a first frequency range of the first bandpass filter is between the portion of the scene and the second detector, initiating storage of a second image of the scene, the second image captured while the portion of the scene has the second alignment with the second detector.

An image processing apparatus includes a processor configured to execute: acquiring image data; generating first interpolation image data associated with light having a red wavelength band, second interpolation image data associated with light having a green wavelength band, third interpolation image data associated with light having a blue wavelength band, and fourth interpolation image data associated with narrow band light; performing a color space conversion process for converting each of the first to the third interpolation image data to a luminance component and a color difference component; extracting a first specific frequency component included in the fourth interpolation image data; combining the converted luminance component with the extracted first specific frequency component; and generating color image data based on a combination result obtained by the combining and based on the color difference component.

A method includes capturing, with an image capture device, a first image of a scene while a portion of the scene has a first alignment with a first detector of a focal plane array and a first bandpass filter is between the portion of the scene and the first detector. The method includes, in response to determining that the portion of the scene has a second alignment with a second detector of the focal plane array, the second alignment substantially matching the first alignment, and that a second bandpass filter having a second frequency range that is distinct from a first frequency range of the first bandpass filter is between the portion of the scene and the second detector, initiating storage of a second image of the scene, the second image captured while the portion of the scene has the second alignment with the second detector.

The functional effect of having additional color-sensing cone types in the human eye is implemented by an encoding of some spectral information differently for the left and right eyes. This different encoding for identical features seen by the left and right eyes is interpreted as a perceptively different feature by the human brain, allowing additional spectral information to be conveyed through the limited tristimulus sensitivity of the human eye.

An image quality adjustment device includes: a lighting controller that controls a display panel including a plurality of pixels, each including arrangement of a plurality of subpixels such that the display panel displays a measurement image in which a part of the plurality of subpixels is lit; and a first electric filter that removes at least a spatial frequency component greater than or equal to fd/2 from a first image obtained by capturing the measurement image displayed on the display panel using an capture device when a panel spatial frequency determined by a pixel pitch of the pixel in a direction in which the plurality of subpixels are arrayed is set to fd.

A biological information detection device includes a light source, an image capturing device, and one or more arithmetic circuits. The light source projects dots formed by light onto a target including a living body. The image capturing device includes photodetector cells and generates an image signal representing an image of the target onto which the dots are projected. The one or more arithmetic circuits detect a portion corresponding to at least a part of the living body in the image by using the image signal and calculate biological information of the living body by using image signal of the portion.

An optical filter that suppresses the occurrence of color mixing due to wavelength components on the short wavelength side relative to the desired transmission component. The optical filter includes a metal thin-film filter in which a plurality of openings are periodically arranged, and a first dielectric layer that coats a surface of the metal thin-film filter and coats or fills an interior of the opening of the metal thin-film filter. The optical filter also includes a second dielectric layer having a refractive index lower than a refractive index of the first dielectric layer and formed at least on an incidence surface side of the metal thin-film filter. The present technology can be applied to a hole array filter.

A solid-state imaging device includes a plurality of photoelectric conversion portions each provided to correspond to each of a plurality of pixels in a semiconductor substrate and receiving incident light through a light sensing surface, and a pixel separation portion that is embedded into a trench provided on a side portion of the photoelectric conversion portion and electrically separates the plurality of pixels in a side of an incident surface of the semiconductor substrate into which the incident light enters. The pixel separation portion is formed by an insulation material which absorbs the incident light entering the light sensing surface.

Apparatus for capturing a wide-color-gamut image includes a broadband electronic image sensor; optics gathering light from a scene and focusing an image formed by the gathered light along a light path onto the electronic image sensor; a filter interposed in the light path, constructed and arranged so as to allow individual wavelengths of the wide-gamut-color to pass through it in narrow bands of wavelengths having bandwidths narrower than a few tens of nanometers at each point in time; and a processor connected to the image sensor to capture a sequence of images synchronous with each narrow-band wavelength passed by the filter at each point in time, the processor combining the sequence of images into the wide-gamut-color image. Apparatus for projecting a wide-gamut-color image includes a wide-spectrum image source; optics projecting light from the image source to a display surface along a light path; a filter unit interposed in the light path, constructed and arranged so as to allow each individual wavelength of the wide-gamut-color to pass through it one, narrow-band wavelength at each point in time; and a processor connected to the image source to present a sequence of images synchronous with each narrow-band wavelength passed by the filter at each point in time, thus projecting the wide-gamut-color image.