Provided is an imaging apparatus including: a splitter that splits incident light into pieces of light of two or more wavelength bands; and two or more detectors that detect the pieces of light of two or more wavelength bands respectively and output signals from which wavelengths can be extracted tunably by post-processing.

An image pickup apparatus includes an image pickup member and a laminated optical member that is fixed in frame-shaped fixed areas around respective optical path areas. The fixed areas include a first area and a second area. A width of the first area is greater than a width of the second area. In the laminated optical member, an optical surface central axis deviates from an optical axis toward the first area. In the image pickup member, an image pickup surface central axis that is a central axis of a first main surface deviates from the optical axis.

A fluorescence imaging system is configured to generate a video image onto a display. The system includes a light source for emitting infrared light and white light, an infrared image sensor for capturing infrared image data, and a white light image sensor for capturing white light image data. Data processing hardware performs operations that include filtering the infrared image data with a first digital finite impulse response (FIR) filter configured to produce a magnitude response of zero at a horizontal Nyquist frequency and a vertical Nyquist frequency. The operations also include filtering the infrared image data with a second digital FIR filter configured with a phase response to spatially align the white light image data with the infrared image data. The operations also include combining the white light image data and the infrared image data into combined image data and transmitting the combined image data to the display.

An imaging unit includes: a first lens group configured to form a first optical image; a second lens group configured to form a second optical image; an objective lens group having a first region and a second region; a single image sensor configured to generate an image signal; a first holding frame having a first holding hole and a second holding hole; a second holding frame configured to hold the objective lens group; and a third holding frame configured to hold the image sensor. A depth of field of a first optical system formed of the objective lens group and the first lens group is set so as to entirely include a depth of field of a second optical system formed of the objective lens group and the second lens group and to be deeper than the depth of field of the second optical system.

An image pickup apparatus for endoscope includes an optical member that is a hybrid lens element in which a plurality of optical elements are bonded to each other, at least any one of the plurality of optical elements including a resin lens disposed on a principal surface of a parallel flat glass plate, and an image pickup member that receives an object image brought into focus by the optical member. A surface of the resin lens and the principal surface around the resin lens are covered with a transparent inorganic film such that a boundary between the surface of the resin lens and the principal surface around the resin lens is also covered with the inorganic film.

A flexible tube insertion apparatus includes a flexible tube to be inserted into an insertion target body, a variable stiffness portion that changes a bending stiffness of the flexible tube, a state detection sensor that detects state information of the flexible tube. The apparatus also includes a shape calculator that calculates shape information regarding a shape of the flexible tube based on the state information, an external force calculator that calculates external force information including magnitude of an external force received by the flexible tube based on the state information, and a stiffness controller that controls the variable stiffness portion in accordance with the shape information so that the magnitude of the external force received by the flexible tube becomes smaller than a reference value.

An optical connection module for an endoscope includes: an optical fiber having a fiber end surface and configured to guide a part of emitted light emitted from a light source and incident on the fiber end surface; a ferrule having a ferrule end surface with an opening of a through-hole into which the optical fiber is inserted, the ferrule including a scatterer configured to scatter, in an inside of the ferrule, a part of the emitted light incident on the ferrule end surface, the ferrule being configured to emit scattered light generated by scattering from a side surface; and an optical sensor arranged in the periphery of the side surface of the ferrule and configured to receive the scattered light.

An endoscope includes: a distal end rigid member including a distal end-side end portion and a proximal end-side end portion in the longitudinal axis direction of an insertion portion and a hole provided in the longitudinal axis direction; an objective optical unit inserted into and attached to an inside of the hole in the longitudinal axis direction; a camera unit; and a projecting portion projecting from at least a part of a periphery of the hole, from the proximal end-side end portion to a proximal end side in the longitudinal axis direction, by a length that is equal to or greater than a length up to a gravity center position of the camera unit in the longitudinal axis direction exceeding a connecting portion connecting the objective optical unit and the camera unit, so as to cover a part of an outer peripheral portion of the camera unit.

An optical path deflecting prism for endoscope which is used for observing an object in an oblique direction, includes a first prism and a second prism, and the first prism and the second prism are cemented. The first prism has a first polished surface and a second polished surface. The first reflecting surface is a mirror surface having a mirror coating applied to a polished surface of a flat plate, and is fixed by gluing to the fifth polished surface of the second prism upon adjusting an angle so as to correct an optical-axis shift which occurs due to a manufacturing error of the first prism and the second prism.

An imaging apparatus including a substrate, an imaging device provided on the substrate, and a light emitting device provided on the substrate and having a plurality of nano-structures.