Abstract: An eyepiece optical system includes a focal-plane plate, having a positive refractive power on one side and a diffusion surface on the other side thereof; a reflector which reflects light rays of an object image, formed on the diffusion surface, a predetermined number of times; an optical lens group, by which the object image is observed, in that order along an optical path from the object side to the viewing side; and a condenser lens element, having a positive refractive power, provided between the focal-plane plate and the reflector, the condenser lens element having an aspherical surface formed on at least one side thereof. At least one of the aspherical surface of the condenser lens element has a profile, when viewed macroscopically, such that the positive refractive power thereof increasingly weakens with respect to a direction away from the optical axis.

Abstract: An eyepiece optical system includes a focal-plane plate, having a positive refractive power on one side and a diffusion surface on the other side thereof; a reflector which reflects light rays of an object image, formed on the diffusion surface, a predetermined number of times; an optical lens group, by which the object image is observed, in that order along an optical path from the object side to the viewing side; and a condenser lens element, having a positive refractive power, provided between the focal-plane plate and the reflector, the condenser lens element having an aspherical surface formed on at least one side thereof. At least one of the aspherical surface of the condenser lens element has a profile, when viewed macroscopically, such that the positive refractive power thereof increasingly weakens with respect to a direction away from the optical axis.

Abstract: A finder optical system includes an image inverter optical member and an eyepiece lens system. The eyepiece lens system includes a first lens element, a positive biconvex second lens element, and a meniscus third lens element having a concave surface on the eyepoint side, in that order from the object side. A diopter adjustment operation is performed by moving the second lens element along the optical axis. Conditions (1) and (2) are satisfied: ?0.2<f/f3<0.2??(1), and 2.15<f(L3n?1)/L3b<3.00??(2), wherein f designates the focal length of the entire the eyepiece lens system at a diopter of ?1, f3 designates the focal length of the third lens element, L3n designates the refractive index at the d-line of the third lens element, and L3b designates the radius of curvature of the surface on the eyepoint side of the third lens element.

Abstract: A finder optical system includes an image inverter optical member and an eyepiece lens system. The eyepiece lens system includes a negative first lens element, a positive biconvex second lens element, and a meniscus third lens element having a concave surface on the eyepoint side, in that order from the object side. A diopter adjustment operation is performed by moving the second lens element along the optical axis. Conditions (1) and (2) are satisfied: ?0.2<f/f3<0.2??(1), and 2.15<f(L3n?1)/L3b<3.00??(2), wherein f designates the focal length of the entire the eyepiece lens system at a diopter of ?1, f3 designates the focal length of the third lens element, L3n designates the refractive index at the d-line of the third lens element, and L3b designates the radius of curvature of the surface on the eyepoint side of the third lens element.

Abstract: A focus detection device, which detects a defocus amount based on a phase difference between a pair of object images that are obtained by pupil division and projected onto a pair of areas on a line sensor, includes a parallel line sensor having two line sensor arrays arranged adjacently in parallel, and a correction calculator which corrects the defocus amount according to a phase difference between output signals of the two line sensor arrays of the parallel line sensor.

Abstract: A multifocal intraocular lens simulator includes an optical system enabling an object to be observed therethrough, and a test lens holder which holds a prescribed test intraocular lens. The intraocular lens holder is installed at a position optically conjugate with a position at which an eye of an observer is to be placed. The present invention also teaches a method of simulating a multifocal intraocular lens.

Abstract: A multifocal intraocular lens simulator includes an optical system enabling an object to be observed therethrough, and a test lens holder which holds a prescribed test intraocular lens. The intraocular lens holder is installed at a position optically conjugate with a position at which an eye of an observer is to be placed. The present invention also teaches a method of simulating a multifocal intraocular lens.

Abstract: There is provided a confocal scanning endoscope system, which is provided with a light source that emits light, a scanning unit that deflects the light emitted by the light source so that the light scans on a subject in two dimensions, an objective optical system that directs the light deflected by the scanning unit to the subject, an extraction unit that extracts only part of the light returning from a convergence point at which the light is converged by the objective optical system on an object side, an image formation unit configured to form an image based on the part of the light extracted by the extraction unit, and a display area adjustment unit configured to measure Encircled Energy of the part of the light extracted by the extraction unit and to adjust a display area of the image based on the measured Encircled Energy.

Abstract: A focus detection device, which detects a defocus amount based on a phase difference between a pair of object images that are obtained by pupil division and projected onto a pair of areas on a line sensor, includes a parallel line sensor having two line sensor arrays arranged adjacently in parallel, and a correction calculator which corrects the defocus amount according to a phase difference between output signals of the two line sensor arrays of the parallel line sensor.

Abstract: An optical system of a focus detection apparatus includes a condenser lens positioned behind an expected focal plane of a photographing lens; an auxiliary lens group positioned behind the condenser lens to be coaxial therewith; and a pair of separator lenses positioned behind the auxiliary lens group in close vicinity thereof and integrally molded from resin. An object image formed on the expected focal plane is divided into two images by the pair of separator lenses to be reformed on a pair of areas on a sensor, respectively, and the auxiliary lens group includes a negative lens element made of resin, and a positive lens element made of glass.

Abstract: An optical system of a focus detection apparatus includes a condenser lens positioned behind an expected focal plane of a photographing lens; an auxiliary lens group positioned behind the condenser lens to be coaxial therewith; and a pair of separator lenses positioned behind the auxiliary lens group in close vicinity thereof and integrally molded from resin. An object image formed on the expected focal plane is divided into two images by the pair of separator lenses to be reformed on a pair of areas on a sensor, respectively, and the auxiliary lens group includes a negative lens element made of resin, and a positive lens element made of glass.

Abstract: An optical system for stereoscopic rigid endoscope is provided with first and second objective optical systems arranged to have a predetermined clearance therebetween and an optical path combining system that polarizes light passed through the first and second objective optical systems in directions perpendicular to each other. The optical path combining system parallelly shifts the optical axes of the first and second objective optical systems so that they coincide with each other. The shifting directions of the optical axes form an angle less than 90 degrees. A relaying optical system is provided inside the insertion unit of the endoscope. An optical axis of the relaying optical system is coaxial with the combined optical axes. An optical image separating system separates the light passed through the relaying optical system into first and second components that passed through the first and second objective optical systems and polarized by the optical path combining system, respectively.

Abstract: A condensing optical system, suitable for a scanning confocal optical system (having a composition for scanning a beam spot on a subject surface by swinging a point source of light) and capable of satisfactorily suppressing various aberrations and reducing loss of light quantity, is provided. The condensing optical system, installed in a scanning confocal optical system for obtaining images of a subject surface by scanning a beam emitted from a point source of light by moving the point source which serves as a pinhole for confocal observation, is configured to satisfy the following condition 0.1<|m×NA|<0.2 where “m” denotes magnification of the condensing optical system and “NA” denotes a numerical aperture of the condensing optical system on its subject surface side.

Abstract: An adjustment method includes rotating a pair of magnifying glasses in directions opposite to each other using ?-rotation, and correcting inclination of an image, caused by the ?-rotation, by rotating the pair of magnifying glasses in directions opposite to each other using the ?-rotation, given that rotation about each of axes XL and XR, which respectively correspond to visual axes of left and right eyes when an object distance is infinite in a condition of a primary position, is represented by the ?-rotation, and that rotation about each of axis YL and YR, which are respectively perpendicular to the axes XL and XR and are also perpendicular to a z-axis which perpendicularly intersects with the axis XL at a position of a deflector for the left eye and the axis XR at a position of the deflector for the right eye, is represented by the ?-rotation.

Abstract: There is provided a confocal scanning endoscope system, which is provided with a light source that emits light, a scanning unit that deflects the light emitted by the light source so that the light scans on a subject in two dimensions, an objective optical system that directs the light deflected by the scanning unit to the subject, an extraction unit that extracts only part of the light returning from a convergence point at which the light is converged by the objective optical system on an object side, an image formation unit configured to form an image based on the part of the light extracted by the extraction unit, and a display area adjustment unit configured to measure Encircled Energy of the part of the light extracted by the extraction unit and to adjust a display area of the image based on the measured Encircled Energy.

Abstract: In an optical viewer instrument with a photographing function, there is provided a telescopic lens system for observing objects, and a digital camera system including a solid-state image sensor and a photographing lens system associated with each other such that an object is formed as a photographed image on the solid-state image sensor through the photographing lens system. A manually-operable focussing mechanism is associated with the telescopic lens system and the photographing lens system such that the object is brought into focus through the telescopic lens system, and such that the object is brought into focus through the photographing lens system. Optical parameters are selected such that predetermined conditions are fulfilled, whereby the focussing of the telescopic lens system and the focusing of the photographing lens system can be suitably and properly performed by the focussing mechanism.

Abstract: An optical system for stereoscopic rigid endoscope is provided with first and second objective optical systems arranged to have a predetermined clearance therebetween and an optical path combining system that polarizes light passed through the first and second objective optical systems in directions perpendicular to each other. The optical path combining system parallelly shifts the optical axes of the first and second objective optical systems so that they coincide with each other. The shifting directions of the optical axes form an angle less than 90 degrees. A relaying optical system is provided inside the insertion unit of the endoscope. An optical axis of the relaying optical system is coaxial with the combined optical axes. An optical image separating system separates the light passed through the relaying optical system into first and second components that passed through the first and second objective optical systems and polarized by the optical path combining system, respectively.

Abstract: In an optical viewer instrument with a photographing function, a telescopic lens system for observing an object and a digital camera system for photographing the object are housed in a casing. A manually-operable rotary wheel is rotatably provided in the casing such that a portion of the rotary wheel is exposed to the outside from the casing to bring the object into focus through the telescopic lens system. A display panel unit for displaying the object as a motion picture on a display screen thereof is mounted on the casing so as to be movable between a retracted position, where the display screen of the display panel unit is close to a wall surface of the casing, and a display position, where the display screen of the display panel unit is directed to the ocular-lens-system side of the telescopic lens system. The rotary wheel is arranged such that the exposed portion of the manually-operable rotary wheel is hidden behind the display panel unit when being at the retracted position.

Abstract: A condensing optical system, suitable for a scanning confocal optical system (having a composition for scanning a beam spot on a subject surface by swinging a point source of light) and capable of satisfactorily suppressing various aberrations and reducing loss of light quantity, is provided. The condensing optical system, installed in a scanning confocal optical system for obtaining images of a subject surface by scanning a beam emitted from a point source of light by moving the point source which serves as a pinhole for confocal observation, is configured to satisfy the following condition 0.1<|m×NA|<0.2 where “m” denotes magnification of the condensing optical system and “NA” denotes a numerical aperture of the condensing optical system on its subject surface side.

Abstract: An adjustment method includes rotating a pair of magnifying glasses in directions opposite to each other using &ggr;-rotation, and correcting inclination of an image, caused by the &ggr;-rotation, by rotating the pair of magnifying glasses in directions opposite to each other using the &bgr;-rotation, given that rotation about each of axes XL and XR, which respectively correspond to visual axes of left and right eyes when an object distance is infinite in a condition of a primary position, is represented by the &ggr;-rotation, and that rotation about each of axis YL and YR, which are respectively perpendicular to the axes XL and XR and are also perpendicular to a z-axis which perpendicularly intersects with the axis XL at a position of a deflector for the left eye and the axis XR at a position of the deflector for the right eye, is represented by the &bgr;-rotation.