A light locus of an imaging system is generated in a chromaticity space of two dimensions. The light locus represents a collection of candidate illuminants. The imaging system captures a gray-card image under each of N light sources to obtain N points in the chromaticity space, wherein N is a positive integer no less than three. Each point in the chromaticity space is described by a coordinate pair calculated from red (R), green (G) and blue (B) tristimulus values of the point. A second order polynomial function is calculated by curve-fitting the N points, and the light locus is generated to represent the second order polynomial in the chromaticity space. One of the candidate illuminants from the light locus is then identified as an illuminant for an image captured by the imaging system. A method for color transformation between two imaging systems in a chromaticity space is also described.

A system, method, and computer program product for generating a digital image is disclosed. In use, a first image set is captured by a first image sensor, the first image set including two or more first source images and a plurality of chrominance values, and a second image set is captured by a second image sensor, the second image set including two or more second source images and a plurality of luminance values. Next, a first image of the first source images and a second image of the first source images are combined to form a first pair of source images, and a first image of the second source images and a second image of the second source images are combined to form a second pair of source images. Additionally, a first resulting image by is generated combining the first pair of source images with the second pair of source images. Additional systems, methods, and computer program products are also presented.

A multi-aperture imaging system comprising a first camera with a first sensor that captures a first image and a second camera with a second sensor that captures a second image, the two cameras having either identical or different FOVs. The first sensor may have a standard color filter array (CFA) covering one sensor section and a non-standard color CFA covering another. The second sensor may have either Clear or standard CFA covered sections. Either image may be chosen to be a primary or an auxiliary image, based on a zoom factor. An output image with a point of view determined by the primary image is obtained by registering the auxiliary image to the primary image.

A system, method, and computer program product for generating a digital image is disclosed. In use, a first image set is captured by a first image sensor, the first image set including two or more first source images and a plurality of chrominance values, and a second image set is captured by a second image sensor, the second image set including two or more second source images and a plurality of luminance values. Next, a first image of the first source images and a second image of the first source images are combined to form a first pair of source images, and a first image of the second source images and a second image of the second source images are combined to form a second pair of source images. Additionally, a first resulting image by is generated combining the first pair of source images with the second pair of source images. Additional systems, methods, and computer program products are also presented.

An optical system for use with a multi-channel wide field imaging system, the optical system including an objective lens, a dichroic element to split light into a first wavelength range and a second wavelength range, the dichroic element positioned to receive near parallel chief rays from the objective lens, a first channel lens system to receive light of the first wavelength range from the dichroic element; and a second channel lens system to receive light of the second wavelength range from the dichroic element.

There is provided an imaging device capable of reducing a processing load of signal processing using two images of different wavelengths, and a method of operating the imaging device. The phases of two types of incident light beams having different wavelengths are matched, the two types of incident light beams are polarized into the same polarization direction, a wavelength of one incident light beam of the two types of polarized incident light beams is matched with a wavelength of the other incident light beam, a phase difference is adjusted such that the phase difference between the one incident light beam and the other incident light beam is , the two types of incident light beams being matched with the wavelength of the one incident light beam, and an imaging element simultaneously receives the two types of incident light beams adjusted such that the phase difference is , thereby, optically acquiring the subtraction results of two types of power.

There is provided an imaging device capable of reducing a processing load of signal processing using two images of different wavelengths, and a method of operating the imaging device. The phases of two types of incident light beams having different wavelengths are matched, the two types of incident light beams are polarized into the same polarization direction, a wavelength of one incident light beam of the two types of polarized incident light beams is matched with a wavelength of the other incident light beam, a phase difference is adjusted such that the phase difference between the one incident light beam and the other incident light beam is , the two types of incident light beams being matched with the wavelength of the one incident light beam, and an imaging element simultaneously receives the two types of incident light beams adjusted such that the phase difference is , thereby, optically acquiring the subtraction results of two types of power.

Embodiments of imaging systems and methods of autofocusing are disclosed, for example, using a folded optics configuration. One system includes at least one camera configured to capture a target image scene, including an image sensor comprising an array of sensor elements, a primary light folding surface configured to direct a portion of received light in a first direction, and an optical element having a secondary light folding surface directing light in a second direction. The system can also include a lens assembly having at least one stationary lens positioned between the secondary light folding surface and the image sensor, the at least one stationary lens having a first surface mechanically coupled to the optical element and a second surface mechanically coupled to the image sensor, and at least one movable lens positioned between the primary light folding surface and the optical element.

A head-mounted display (101) includes: an imaging assembly (203) imaging scenery seen by a user to generate a source picture; a storage unit (202) storing color correction factors used for correcting brightness of each of a red, green and blue color components included in a picture; a correction picture generator (212) performing color correction processing for enhancing a color component with a relatively low color correction factor stored in the storage unit (202), of the red, green and blue color components forming the source picture, to generate a correction picture; a picture display assembly (207) displaying the correction picture in the field of view of the user under a condition where he/she is able to perceive the outside world; and a special picture processor (213) performing picture processing for overlaying the correction picture and the source picture on each other for display.

A multispectral image capture device includes a filter wheel (4) and an image sensor. The filters (41-46) are located close to a focusing plane of a light beam used to form the images, and at least one of the filters is more angularly narrow than the optical field of the image sensor. The production of the filter is thereby facilitated. Advantageously, the filters are closer to one another in the wheel such that multiple filters are in the optical field of the sensor simultaneously. Each multispectral image can be captured more quickly than when each filter covers the entire optical field of the sensor.