A novel dual-path-endoscope where a multi-function light source produces a first-light and a second-light toward an object. The first-light exhibits first-light-characteristics. The second-light exhibits second-light-characteristics different from the first-light-characteristics. The endoscope includes two light-paths, the disparity there between is larger than zero. Each light-path includes a respective pupil and a respective light-separator coupled with the pupil, transmitting there through one of the first-light and the second-light, associating the first-light and the second-light with a respective light-path. The dual-channel-imager includes two imager sensors, each associated with a respective light-path and optically coupled with a respective light-separator. Each imaging-sensor exhibits sensitivity to the characteristics of the respective one of the first-light and the second-light. A first imaging-sensor acquires a first-image of the first-light reflected of the object and a second imaging-sensor acquires a second-image of the second-light reflected of the object. The processor processes the acquired images.

[Object] In a configuration in which an image of a target is captured using a plurality of imaging elements, the plurality of imaging elements can be efficiently disposed in a limited space. [Solving Means] A branching optical system includes: a first branching optical system that separates first light belonging to a predetermined wavelength band from incident light in a first direction that is a surface direction of a plane including an optical axis corresponding to a normal direction of an incidence surface on which the incident light is incident; and a second branching optical system that is provided subsequent to the first branching optical system and separates, from second light after the first light is separated from the incident light, third light that is a part of the second light, in a second direction crossing the plane.

An image capture device may capture visible and infrared light, and image analysis may be used to generate a map of the Normalized Difference Vegetation Index (NDVI) of healthy vegetation. Because NDVI data focuses on red and near infrared (NIR) reflectance of plants, NDVI data may be generated using an aircraft-mounted camera with optical filtering to collect various wavelengths. To reduce the size, weight, complexity, and cost of the image analysis system, a multiband optical filter may be used to capture multiple passbands simultaneously.

Systems and methods for implementing array cameras configured to perform super-resolution processing to generate higher resolution super-resolved images using a plurality of captured images and lens stack arrays that can be utilized in array cameras are disclosed. Lens stack arrays in accordance with many embodiments of the invention include lens elements formed on substrates separated by spacers, where the lens elements, substrates and spacers are configured to form a plurality of optical channels, at least one aperture located within each optical channel, at least one spectral filter located within each optical channel, where each spectral filter is configured to pass a specific spectral band of light, and light blocking materials located within the lens stack array to optically isolate the optical channels.

An endoscope includes: an aperture portion having an opening to which light from an observation target site is incident; a filter unit that has a plurality of filters and selectively transmits light based on any one of the filters; a color separation prism that is formed by a plurality of separation prisms which separate light, which has transmitted through the filter unit, into beams of light having different color components from each other; a plurality of image sensors that are provided so as to respectively correspond to the separation prisms and capture an image based on the beams of light; a signal output unit that outputs image signals captured by the image sensors respectively; and a filter disposing unit that disposes any one of the plurality of filters so that the light is incident to the disposed one of the plurality of filters.

An apparatus comprises a mount body by which the apparatus is secured to a structure. A camera assembly, fixed to the mount body, includes an image sensor adapted to capture images within its field of view. A lighting assembly, rotatably connected to the mount body, houses one or more light sources including a directional light source. A control-board assembly, fixed to the mount body, houses control boards including one or more processors configured to acquire information about an object, to associate a location within the field of view of the image sensor with the object, to point light emitted by the directional light source at the location associated with the object by rotating the lighting assembly and turning the laser assembly, and, based on an image acquired from the camera assembly, to detect change within the field of view of the image sensor corresponding to placement or removal of the object.

A dual-aperture zoom camera comprising a Wide camera with a respective Wide lens and a Tele camera with a respective Tele lens, the Wide and Tele cameras mounted directly on a single printed circuit board, wherein the Wide and Tele lenses have respective effective focal lengths EFL.sub.W and EFL.sub.T and respective total track lengths TTL.sub.W and TTL.sub.T and wherein TTL.sub.W/EFL.sub.W>1.1 and TTL.sub.T/EFL.sub.T<1.0. Optionally, the dual-aperture zoom camera may further comprise an optical OIS controller configured to provide a compensation lens movement according to a user-defined zoom factor (ZF) and a camera tilt (CT) through LMV=CT*EFL.sub.ZF, where EFL.sub.ZF is a zoom-factor dependent effective focal length.

Systems and methods for implementing array cameras configured to perform super-resolution processing to generate higher resolution super-resolved images using a plurality of captured images and lens stack arrays that can be utilized in array cameras are disclosed. An imaging device in accordance with one embodiment of the invention includes at least one imager array, and each imager in the array comprises a plurality of light sensing elements and a lens stack including at least one lens surface, where the lens stack is configured to form an image on the light sensing elements, control circuitry configured to capture images formed on the light sensing elements of each of the imagers, and a super-resolution processing module configured to generate at least one higher resolution super-resolved image using a plurality of the captured images.

Digital camera systems and methods are described that provide a color digital camera with direct luminance detection. The luminance signals are obtained directly from a broadband image sensor channel without interpolation of RGB data. The chrominance signals are obtained from one or more additional image sensor channels comprising red and/or blue color band detection capability. The red and blue signals are directly combined with the luminance image sensor channel signals. The digital camera generates and outputs an image in YCrCb color space by directly combining outputs of the broadband, red and blue sensors.

An illumination radiates a visible light or a near-infrared light. A lens images a light from a subject. A beam splitter disperses the visible light and the near-infrared light. A color imaging device images a reflecting light from the subject illuminated with the visible light and includes an imaging device having a red filter. A black-and-white imaging device images the near-infrared light dispersed by the beam splitter. A pixel pitch of the black-and-white imaging device that images the near-infrared light dispersed is larger than a pixel pitch of the color imaging device. A sampling position for the near-infrared light is displaced in a pixel arrangement horizontally or vertically with respect to a sampling position for red in a color image.