A power supply apparatus for an endoscope includes a plurality of power supply circuits, a plurality of power changeover switches, and a power control circuit. The power control circuit performs an operation to determine, when one power changeover switch provided on one power supply line connecting one power supply circuit of the plurality of power supply circuits and one electronic part of the plurality of electronic parts in each order of the power-on sequence is set to off, whether an output voltage of the one power supply circuit is normal or not and an operation to start a supply of one drive voltage required to drive the one electronic part according to a judgement result that the output voltage of the one power supply circuit is normal.

An optical system includes in order from an object side, an objective optical system, a /4 wavelength plate including one birefringent material, a polarizing beam splitter which splits light from the objective optical system into two, and an image sensor which picks up two images split. The polarizing beam splitter causes to occur an axial astigmatism of an opposite sign with respect to an axial astigmatism occurred due to the /4 wavelength plate, the following conditional expression (1) is satisfied.
1.1Fno/(d/|n|)49(1) where, Fno denotes an effective F-number of the objective optical system, d denotes a thickness of the /4 wavelength plate, and n denotes a birefringence of the /4 wavelength plate for an e-line, provided that, |0.01|<n.

Disclosed herein are imaging systems and methods for simultaneous near-infrared light and visible light imaging of a sample comprising: a detector to form a fluorescence image of the sample and a visible image of the sample; a light source configured to emit infrared light to induce fluorescence from the sample; and a plurality of optics arranged to direct the infrared light toward the sample and form the fluorescence image of the sample and the visible light image of the sample on the detector, wherein the infrared light is directed to the sample substantially coaxially with fluorescence light received from the sample in order to decrease shadows.

An optical path turning module includes an optical path turning unit, a carrier, a fixing element and a driver. The optical path turning unit includes a sloping surface. A light beam enters the optical path turning unit along a first axis, is reflected by the sloping surface, and leaves the optical path turning unit along a second axis. The carrier is configured to fix the optical path turning unit and includes a main body and a plurality of first clamping portions. The main body is sloped with respect to the second axis, and the first clamping portions extend from the main body in a direction parallel to the second axis. The carrier is disposed in the fixing element. The driver is configured to drive the carrier to rotate about a third axis with respect to fixing element. The third axis is perpendicular to the first axis and the second axis.

An endoscope device includes an imaging unit and an operation unit that is configured to receive results of an assessment on an endoscopic image of an object as captured by the imaging unit. A retrieval control unit is configured to retrieve one of assessment assist images stored in a data accumulation unit based on information on the assessment results. A display control unit is configured to display the retrieved one assessment assist image along with the endoscopic image on a display unit.

Disclosed is a light source device for endoscope including: a front panel which includes a touch portion and a display portion; a touch board which is disposed in a rear side of the front panel, and comprises an electrostatic touch sensor that is located in a position corresponding to the touch portion and detects an input generated in the touch portion; a light source board which is disposed in a rear side of the touch board, and comprises a light source configured to irradiate light to at least one of the display portion and the touch portion; and a guide unit which is provided between the touch board and the light source board, and guides the light irradiated from the light source.

An optical component assembly method including shrinking a first end of a heat shrink tube about a first optical component, inserting a loading portion of a loading tube into a second end of the heat shrink tube, radially-inserting a plurality of optical components into a staging portion of the loading tube thereby forming a line of optical components, the staging portion being seamlessly coupled to and integrally-formed with the loading portion, moving the line of optical components from the staging portion into the loading portion, and removing the loading portion from between the line of optical components and the heat shrink tube thereby depositing the line of optical components in the heat shrink tube. The line of optical components is fixed and optically aligned within the heat shrink tube by applying radial pressure, axial pressure and heat to the line of optical components simultaneously.

The present disclosure is directed to an optical adapter for an optical scope. The optical scope includes a tube defining a conduit. The optical adapter is coupled to an end of the tube. The optical adapter defines a proximate end and a distal end. The optical adapter includes a casing defining a longitudinal direction. The casing includes a first wall and a second wall, in which the first wall and the second wall define a first viewing port therebetween. The second wall defines a second viewing port. The optical adapter further includes a hinge coupled to the first wall, a reflecting lens defining a first end separated from a second end in the longitudinal direction, in which the first end is coupled to the hinge, and an actuator coupled to the first wall and to the second end of the reflecting lens. The actuator pivots the reflecting lens about the hinge from a retracted position adjacent to the first wall to an extended position toward the second wall.

Image acquisition apparatuses, spectral apparatuses, methods and storage mediums for use with same are provided herein. At least one apparatus includes: a diffraction element irradiated by a light; a fiber for receiving reflected scattered light from a subject; a diffraction grating dispersing the transmitted light into light fluxes of wavelength bands again; an optical system imaging the split light fluxes; and an imaging device near the focal point of the optical system. An image is changed by rotating the diffraction grating, from which a two-dimensional image is acquired. The transmitted light may be branched into two or more, and input to a collimator lens and imaged as multiple spectral sequences by the optical system. At least one apparatus may form light fluxes traveling at different angles; and may acquire spectral information of the reflected and scattered light. Preferably, for the luminous fluxes, no gap exists in an image.

A telescope remote display and control system for viewing objects through a telescope and controlling the telescope remotely includes a wearable display, a manual controller, a camera, an mechanical adjuster, and an integration system, all of which are electrically interconnected. In the preferred embodiment, the camera, mechanical adjuster, and integration system are all attached to a target telescope and tripod assembly, while the wearable display and manual controller are positioned remotely. The integration system operates as the control hub, allowing a user to view images from the telescope with the wearable display by way of signals from the camera and control the positioning of the telescope with the manual controller through manipulation of the mechanical adjuster.