Abstract: The portable microscope includes an end plate for improved inspection of the end surface of a fiber optic cable at a connection point in a fiber optic system. The end plate is mounted on the head unit housing of the microscope and includes a tubular aperture for receiving and positioning the end of the fiber optic cable for microscopic inspection. A reflection bowl is formed about the tubular aperture on the inner surface of the plate to direct more light to the end of the fiber optic cable. The tubular aperture may be formed in an adapter and the adapter may be secured in a threaded aperture of the end plate. A rocker head adapter may be used to provide both direct and angled viewing of the end surface of a glass fiber. Spacer blocks with reflective surfaces are used to position the end plate on the microscope and to direct more light towards the end surface of the fiber optic cable.

Abstract: A microscope apparatus that has an electronic image pickup device arranged on an image surface of an imaging optical system, a component for separating light from a light source into two portions, a device for changing a phase difference between the two portions of light, a device for storing information on the images picked up by the image pickup device, and information processor for processing the information of images. The images are picked up by the electronic image pickup device as the phase difference is changed, and the information on the images is multiplied by a periodic function, as a weight function, which is given the phase difference as variable, and a resultant product is integrated so that a differential interference microscope apparatus capable of accurately obtaining a phase distribution of the object or a phase-contrast microscope apparatus capable of effectively enhancing a resolving power without lowering an image contrast is obtained.

Abstract: Method and apparatus for illuminating a transparent material for identifying individual features in the material having similar refractive indices, without using a phase-contrast microscope, by illuminating the material by light directed at an angle to a reflective surface which directs the light through the material to a viewing device such as a microscope.

Abstract: A stereo microscope arrangement includes an objective used in common, at least a first and a second pair of stereoscopic observation beam paths and an illuminating unit with at least one deflecting element that deflects illuminating light in the direction of the object plane. The illuminating unit is arranged so that it can be mounted in at least two different positions relative to the stereoscopic beam paths. Accordingly, optimized illuminating conditions can be selectively placed at the disposal of the main observer or the co-observer.

Abstract: An exchangeable condenser system for a phase-contrast illuminating system (12) for microscopes has a plurality of different light rings (5), arranged on a nosepiece plate (4), assigned to the condenser optical system (6). The condenser optical system (6) can be exchanged independently of the light rings (5), the focal lengths F.sub.n of the exchangeable condenser optical systems (6) being selected relative to one another in the ratio F.sub.n =F.sub.0 *X.sup.n and the average diameters D.sub.n of the light rings (5) being selected relative to one another in the ratio D.sub.n =D.sub.0 *X.sup.n, where X>0, n=0,1,2,3, . . . .

Abstract: An objective unit in which illumination light is applied through an annular illumination light path surrounding lenses for guiding observation light coming from an object of observation, and which includes a shared lens for guiding the illumination light from the illumination light path to the object of observation and for guiding the observation light to the lenses.

Abstract: A system enabling conversion of a conventional ringlight for differential illumination such as dark field or Rheinberg illumination is disclosed. The system comprises a ringlight having an annular light emitting portion and a hood that fits over the ringlight. The hood has an aperture and an annular reflective surface, disposed opposite the light emitting portion, that reflects the light from the ringlight through the aperture. An angle of the annular reflective surface is selected relative to a direction of light from the ringlight to form a cone of light exiting the aperture. To ensure good contrast, a light baffle in the form of a sleeve, inserted into the ringlight, may be incorporated to prevent stray light from the ringlight from directly exiting through the aperture. The differential illumination produced by the invention is applicable to machine vision applications, but also microscopy, gemology, and serology, for example.

Abstract: Apparatus are disclosed that perform, on demand, both near-field microscopy (NFM) and light-microscopy (e.g., bright-field microscopy or phase-contrast microscopy) of a specimen. The apparatus comprises an NFM microscope including an NFM probe, a first condenser lens system that converges a center portion of an illumination-light flux at a first terminus of the NFM probe, and a second condenser lens system that converges an annular portion of the illumination-light flux at a specimen to illuminate the specimen by Kohler illumination. Evanescent light from a distal terminus of the NFM probe passes to a locus on the specimen. Downstream optics capture light transmitted and/or scattered from the specimen from the NFM probe and from the Kohler illumination to produce both a light-microscope image of the specimen and an NFM image of the specimen.

Abstract: An display apparatus has an image displaying device for modulating light by a spatial light modulation element and displaying an image, a relay optical system for forming the image on an imaging plane at a location differing from the image displaying device, an eyepiece optical system for directing the light from the imaging plane to an observer's pupil, and light beam controlling device provided in a portion of the relay optical system for controlling the amount of transmission of a light beam from the image displaying device correspondingly to the inclination of the contrast distribution of the light beam.

Abstract: A phase contrast microscope including an illuminating optical system, a ring slit arranged at a pupil of the illuminating optical system, an imaging optical system, and a phase plate arranged at a pupil of the imaging optical system which is conjugate with the pupil of the illuminating optical system with respect to a specimen plane on which a specimen under inspection is placed. The phase plate is formed by a liquid crystal and a pair of transparent ring-shaped electrodes arranged on both sides of the liquid crystal. A voltage applied across the liquid crystal via the electrodes is changed such that a phase difference introduced by the phase plate is set to .+-..pi./2 to obtain a dark contrast image and a bright contrast image. A difference between these dark and bright contrast images is derived to obtain a phase contrast image having high contrast and resolution.

Abstract: An illuminating device for a stereo microscope having an objective with variable imaging focal intercept includes first coupling mechanism, which effects a coupling between the imaging focal intercept of the objective and the likewise adjustable focal intercept of the illuminating optical system, separate from the observation optics, in such a manner that the illuminating focal intercept is in agreement with the imaging focal intercept of the objective. Moreover, adjusting mechanism is provided for the defined adjustment of the diameter of the illuminated field. In particular, the illuminating device is suitable for a surgical microscope.

Abstract: To provide a surgical microscope comprising a microscope collimator for enabling the operator to easily recognize the swivel center of the microscope body regardless of what position the microscope body moves for easy setting of the swivel center point of the microscope body, a surgical microscope pivotally supporting a microscope body having, an observation optical system with one point on an observation optical axis of the microscope body as the swivel center. The surgical microscope comprises index projectors as swivel center visible indicators being capable of recognizing the swivel center. This configuration enables the operator to easily recognize the swivel center of the microscope body for easy setting of the swivel center point of the microscope body.

Abstract: An inexpensive, simple and easy-to-use illuminator element--consisting of chromophores, particularly fluorophores, and/or light-scattering bodies in a stable, typically a polymer plastic, matrix--completely replaces an infinite set of condensers for a optical microscope, and works equally well with microscope objective lenses of any and all numerical apertures. Illuminator elements of a fluorescent type are employed in combination with a primary source of light that is external to the illuminator element itself, and that is preferably but a simple incandescent light bulb. Nonetheless to be energized with spectrally impure light, each illuminator element produces spectrally pure light(s) of a predetermined color or colors, including a pseudo-white light. Sets of illuminator elements permit the ready production of colored light(s) of any desired spectral characteristics from primary light sources that are no more sophisticated, nor any more expensive, than common electric light bulbs.

Abstract: The portable microscope includes an end plate with a reflective inner surface for improved inspection of the end surface of a fiber optic cable at a connection point in a fiber optic system. The end plate is mounted on the head unit housing of the microscope and includes a tubular aperture for receiving and positioning the end of the fiber optic cable for microscopic inspection. A bowl is formed about the tubular aperture on the inner surface of the plate to direct more light to the end of the fiber optic cable. The outer surface of the plate includes a positioning tube for receiving a ferrule with the end of the fiber optic cable and directing the ferrule and fiber optic cable through the aperture into the bowl.

Abstract: A plurality of light emitting diodes are secured coaxially around the lower end of a cylindrical objective lens housing in radially spaced, circular arrays or rings disposed coaxially of the housing. The diodes in each ring are equi-angularly spaced from each other about the axis of the housing; and their light emitting ends overlie a work table so as to direct beams of light obliquely downwardly onto an object supported thereon. The diodes are energizable in generally pie-shaped sectors disposed coaxially of the housing so that arcuate clusters of diodes in a given segment may be illuminated to enable the orientation of the resultant illumination to be varied. The diodes of each ring may have their beam axes inclined at different angles to the axis of the housing so that the inclination of the projected illumination may be varied by selected energization of the rings; and a collimating lens may be secured over the light emitting end of each diode.

Abstract: Methods and apparatus for center masking a condenser lens of a transmitted light microscope to simultaneously maximize resolution, contrast and depth of field utilizing at a conjugate plane of the aperture plane where an image of the rear aperture of the condenser lens has been created, a plurality of light sources to illuminate two or more of the faces of a multi-face mirror in the shape of a pyramid which moves relative to the light sources to vary the amount of center masking continuously over a range including zero while directing multiple oblique beams of light onto the objective lens.

Abstract: The invention provides a switchable bright-field transmitted-light illumination device for microscopes which provides for in each case two objectives of different apertures in both switch positions a simple automatic illumination arrangement without adjustment of the position and of the opening of the diaphragms. For this purpose, in an illumination device, comprising light source 1, collector 2, field diaphragm 3, aperture diaphragm 4 and basic condenser 7 with removable condenser head 8 or condenser lens element 11, which can be switched in alternatively to the condenser head 8 between the aperture diaphragm 4 and the basic condenser 7, the aperture diaphragm 4 is arranged between the collector 2 and the field diaphragm 3 and is imaged by an intermediate imaging by at least two auxiliary lenses 5 and 6 into a plane 12 conjugate with the aperture diaphragm 4.

Abstract: The apparatus has a fired cartridge mounting device for holding the cartridge substantially aligned with a longitudinal axis with a primer surface of the cartridge substantially perpendicular to the axis, a cartridge microscope mounted with its optical axis substantially parallel to the longitudinal axis, a focusing mechanism for focusing the microscope to image a breech face impression on the primer surface and a firing pin impression surface in the primer surface, and an axisymmetric light source mounted to project axially symmetric light onto the breech face impression and the firing pin impression surface about the longitudinal axis. Images of the breech face and the firing pin impressions can be used for comparative analysis independently of an angular orientation of the cartridge held by the mounting device.

Abstract: An electron beam apparatus focusses an electron beam onto a specimen by means of an objective magnetic lens. In order to detect changes in the height of the specimen, a laser light beam from a laser source is incident on the specimen and the reflected laser beam is detected by a light detector. Any change in the height of the specimen changes the path of the laser beam to the detector. Therefore, by monitoring the detector, the focussing of the electron beam on the specimen can be controlled by varying the current to an excitation coil of the objective magnetic lens or by moving the specimen via a mounting stage. At least one of the pole pieces of the objective lens is on the opposite side of the path of the laser beam to the source of the electron beam, so that the objective magnetic lens may be close to the specimen, permitting a short focal length. Thus, the laser beam may pass between the pole pieces. An optical microscope may also be provided to permit the specimen to be viewed.

Abstract: A video microscope capable of optionally and continuously varying image pickup magnifying power of an observed object over a wide range without requiring replacement of a lens. A lens barrel in which a lens system is arranged is slidably positionally adjusted relative to an observation stand in which an illuminating light source is arranged by means of an objective distance adjusting mechanism, to thereby adjust a relative distance between the observed object and an objective side of the lens system. Also, a cylinder of a video signal converting section in which a two-dimensional CCD element is provided is slidably positionally adjusted relative to the lens barrel by means of an enlargement (reduction) magnification and focus adjusting mechanism, resulting in desired magnifying power of the observed object being readily obtained.

Abstract: In order to control the movement of a single neutral atom or a small number of neutral atoms to trap the neutral atom or atoms at a distal end of an optical fiber probe, a laser light having a frequency which is slightly lower than a resonance frequency of the atom is made incident upon a proximal end of the optical fiber probe, and an evanescent light is generated from a sharpened distal end of the optical fiber probe whose tip is sharpened such that its radius of curvature is smaller than one wavelength of the laser light. The distal end of the optical fiber probe is brought close to the neutral atom or atoms to trap the neutral atom or atoms within an existing volume of the evanescent light. When the light frequency is changed to a value slightly higher than the resonance frequency of the atom, the trapped neutral atom or atoms are pushed out of the existing volume of the evanescent light. The crystal growth can be performed with a single atom level.

Abstract: A microscope illuminating apparatus includes a light-shielding tube surrounding an objective lens, detachably mounted on a revolver of a system microscope in order to guide illumination light to irradiate an observation field, thus separating an illumination optical path and an observation optical path. An annular illuminating section serving as a light source of the illumination light is provided at a position to oppose an end portion aperture of the illumination optical path in the revolver.

Abstract: The high intensity illuminator of the invention includes a mounting fixture, a receiving surface spaced from the mounting fixture, and a plurality of semiconductor illumination sources which are implemented, most preferably, by light emitting diodes or laser diodes. Each illumination source is operable for emitting an outwardly-diverging illumination cone along an axis of illumination of the source at a predetermined illumination wavelength. The plural illumination sources are mounted on the mounting fixture such that their illumination cones are overlappingly coincident on a selected portion of the receiving surface to provide at the receiving surface portion a highly uniform illumination of high intensity at the predetermined wavelength.

Abstract: A conical illuminator for use in colorimetry, spectrophotometry, densitometry or sensitometry. In a preferred embodiment, light from a source such as a pulsed xenon lamp is integrated within a integrating chamber. The light source may be placed in a second integrating chamber adjacent to the aforementioned integrating chamber. Alternatively, the lamp may be placed directly within the integrating chamber. The light is emitted through an exit port and conformed to a conical configuration, according to a pre-selected standard, via an annular stop. An imaging optic relays the conformed light uniformly onto a sample plane. The annular stop is placed at or near the tangential focal length of the imaging optic. The annular stop may be coated with a light absorbing coating, or can be formed with a grooved or mirrored surface. Alternatively, in lieu of an integrating chamber, a diffuser may be employed for homogenizing the light. Various configurations of the imaging optic and annular stop are possible.

Abstract: Viewer apparatus for object sorting machines and illumination system for such viewers, the viewer in one embodiment having a housing with a viewing device and a light source mounted therein and an opening through which objects to be sorted pass, with one or more reflectors disposed in the housing to reflect light onto portions of the object.

Abstract: A nanometer dimension light source includes a source of excitation and an active, electrooptic or chemilluminescent material such as crystalline anthracene. The material is introduced into a confined space having molecular dimensions or is shaped to a point of molecular dimensions. The material is surrounded by an insulator such as a glass pipette which also forms the confined space and which also serves as a reflector for radiation produced in the material. An electric field is imposed on the active medium, injecting holes and electrons which recombine to produce light within the small dimensions of the pipette.

Abstract: A documentation illumination module by which full illumination of a properly oriented image of a microscope's field-of-view is returned to a documenting camera or the like. The module includes a cavity with a forming and field-of-view controlling lens system, channel for returning the image, focusing and magnifying lenses in the image channel, and an iris across the image channel. Fiber optics light is transmitted through the cavity and its lens system to a microscope and its field-of-view, then returned to module and to binoculars for an observer (surgeon), without need of beam splitting optical elements. Full light is available to camera and observer. The focusing and magnifying lenses are mounted in an alternatively positionable lens system, while a zoom lens assembly can be substituted therefor.