Abstract: An imaging spectrometer includes an all-reflective objective module that receives an image input and produces an objective module output at an exit slit, and an all-reflective collimating-and-imaging module that receives the objective module output as an objective-end input and produces a collimating-end output, wherein the collimating-and-imaging module comprises a reflective triplet. A dispersive element receives the collimating-end output and produces a dispersive-end input into the collimating-and-imaging module that is reflected through the collimating-and-imaging module to produce a spectral-image-end output. An imaging detector receives the spectral-image-end output of the collimating-and-imaging module. The objective module may be a three-mirror anastigmat having an integral corrector mirror therein, or an all-reflective, relayed optical system comprising a set of five powered mirrors whose powers sum to substantially zero.

Abstract: A method and apparatus or configuration generates light of a given polarization state (P). A polarization state-sensitive beam splitter is acted upon by light (L) at an input (E1), light (LP) of the given polarization state being output by the beam splitter (1) at a first beam splitter output (A1). Light (LS) with polarization state (S) that is perpendicular to the given state (P) is changed with respect to this state and also output. The light of the changed polarization state again acts upon the polarization state-sensitive beam splitter at the input (E1). The apparatus or configuration achieves this by having the optic input (E3) of a polarization state-changing structural element whose optic output (A3) is operationally connected to the optic input (E1) of the polarization state-sensitive beam splitter, operationally connected to the second optic output (A2).

Abstract: The invention according to a first aspect may include an optical system. The optical system may have an axial axis. This optical system may have a number of primary mirror segments. A number of reflectors may be arranged about the axial axis. The primary mirror segments may be configured to reflect a number of principal rays along a first set of chords to corresponding reflectors. These reflectors may be configured to reflect the corresponding principal rays along a second set of chords. Both the first set of chords and the second set of chords may have an angle in excess of 45 degrees with respect to the direction of the axial axis. The invention according to a first aspect may also include a second set of reflectors. The second set of reflectors may be configured to direct the light to an image plane. Other aspects of the invention may include a method of receiving light using an optical system configured to spiral light though the system and a method of making such a system.

Abstract: The invention relates to a device with a detector element for receiving a light beam reflecting on an object, wherein means for detecting the light beam are provided in the detector element. The invention also relates to a method for distance measurement using said receiver device. A device for determining the distance between a vehicle and an obstacle or a vehicle driving ahead is already known as per DE 197 13 826 A1, wherein a pulsed laser beam serving as send signal scans line-by-line a two-dimensional area using a self-rotating polygonal mirror, wherein said polygonal mirror has a plurality of mirror surfaces that are bent at different angles. The pulse beam reflecting on the object is focused on a detector element by optical lenses.

Abstract: The present invention discloses an image-forming optical system provided with a plurality of curved mirrors whereby two points at different distances are made to have an optically conjugate relationship, sequentially starting with a first conjugate point which is nearer when an optical path is traced from the first conjugate point to a second conjugate point which is farther, comprises, a first mirror which reflects luminous flux from the first conjugate point to transform the luminous flux into substantially parallel luminous flux, and a second mirror which reflects the luminous flux reflected by the first mirror while keeping the luminous flux substantially parallel.

Abstract: A projection optical system for projecting an image of a first object onto a second object includes a first imaging optical system that forms a first intermediate image of the first object, and includes a lens, a second imaging optical system that forms a second intermediate image of the first object, and includes a lens and a concave mirror, and a third imaging optical system that forms an image of the first object onto the second object, and includes a lens, wherein the first, second and third imaging optical systems are arranged along an optical path from the first object in this order, and 0.7<|?1·?2|<3.0 is met where ?1 is a paraxial magnification of the first imaging optical system, and ?2 is a paraxial magnification of the second imaging optical system.

Abstract: A device for reflecting an image to a user's eyes that includes a viewing member having an interior mirror positioned in angled alignment with the user's eye; and an exterior mirror positioned in spaced alignment to the interior mirror. The exterior mirror is adjustable with respect to the interior mirror. The device further includes a pair of interior mirrors positioned in angled alignment to the user's eyes; and a pair of exterior mirrors in spaced alignment to the interior mirrors.

Abstract: According to one aspect of the present invention, an apparatus for optically combining light beams is disclosed. The apparatus includes a set of prism shaped doorways configured to receive output beams from at least one optical device. Each of the plurality of doorways has a common refractive index. The apparatus also includes a set of spherical mirrors disposed substantially parallel to the plurality of doorways. Each mirror is associated with one of the plurality of doorways. The apparatus further includes a boundary layer disposed between the set of doorways and the set of mirrors. The boundary layer has a refractive index greater than the common refractive index of the plurality of doorways. The common refractive index of the set of doorways and the refractive index of the boundary layer are configured to change the angle of each of the received output beams to combine the set of received output beams into a single output beam.

Abstract: A catoptric projection optical system for projecting a reduced size of a pattern on an object surface onto an image surface and for serving as an imaging system that forms an intermediate image between the object surface and image surface, includes six or more mirrors, wherein a position of an exit pupil with respect to the intermediate image is located between the object surface and image surface, and wherein the largest angle between principal rays and an optical axis for angles of view at the position of the exit pupil is sin?1NA or smaller, where NA is a numerical aperture at the side of the image surface.

Abstract: An optical communication system for transmitting multiple optical beams, each at a different wavelength is disclosed. The optical communication system includes a laser array having multiple laser transmitters transmitting multiple optical beams, each at a different wavelength. The optical communication system further includes a diffraction grating optically coupled to the laser array, the diffraction grating diffracting each of the optical beams at a substantially equal diffraction angle to form a combined optical beam. The combined beam is then focused into an optical communication media.

Abstract: An all-reflective, relayed optical system is arranged along a beam path. The optical system includes a first mirror having positive optical power, and a second mirror having a negative optical power, wherein the second mirror receives the beam path reflected from the first mirror and wherein an intermediate image is formed after the beam path reflects from the second mirror. The optical system further includes a third mirror having positive optical power, wherein the intermediate image on the beam path is reflected from the third mirror; a fourth mirror having a negative optical power, wherein the beam path reflected by the third mirror is reflected by the fourth mirror, and a fifth mirror having positive optical power, wherein the beam path reflected by the fourth mirror is reflected by the fifth mirror to an image location.

Abstract: A method for manufacturing an apparatus and the apparatus being configured to convert a first distribution of an input radiation to a second distribution of output radiation. The method consists of the steps of generating a two-dimensional representation of at least three active optical surfaces of an optical device including calculating a segment of a first surface based on edge ray sets as a first generalized Cartesian oval, calculating a segment of an entry surface based on the edge ray set as a second generalized Cartesian oval, calculating a segment of a second surface based on the edge ray set as a third generalized Cartesian oval, and successively repeating the steps of calculating the segment of the first surface and calculating the segment of the second surface in a direction towards a source, and rotationally sweeping the two-dimensional representation about a central axis providing a three-dimensional representation of the optical device.

Abstract: An optical element formed from a transparent optical material includes two refraction surfaces, a first reflection surface group having a plurality of internal reflection surfaces arrayed in a predetermined direction, a second reflection surface group opposing the first reflection surface group and having at least one internal reflection surface and two side surfaces opposing each other in parallel to the predetermined direction. Light incident from one of the refraction surfaces is alternately reflected by the internal reflection surfaces of the first reflection surface group and the internal reflection surface of the second reflection surface group and guided to the other refraction surface.

Abstract: An imaging spectrometer includes an all-reflective objective module that receives an image input and produces an objective module output at an exit slit, and an all-reflective collimating-and-imaging module that receives the objective module output as an objective-end input and produces a collimating-end output, wherein the collimating-and-imaging module comprises a reflective triplet. A dispersive element receives the collimating-end output and produces a dispersive-end input into the collimating-and-imaging module that is reflected through the collimating-and-imaging module to produce a spectral-image-end output. An imaging detector receives the spectral-image-end output of the collimating-and-imaging module. The objective module may be a three-mirror anastigmat having an integral corrector mirror therein, or an all-reflective, relayed optical system comprising a set of five powered mirrors whose powers sum to substantially zero.

Abstract: The invention is an apparatus for lengthening the path of a light beam. The apparatus includes an at least partially enclosed chamber having a first opening and a second opening. A first reflective surface is disposed within the chamber and is obliquely oriented with respect to an incoming path of the beam. The beam reflects off of the first reflective surface after the beam enters the chamber through the first opening. Second and third reflective surfaces are disposed within the chamber and are generally parallel to the incoming path of the beam. The beam is reflected a plurality of times between the second and third reflective surfaces after the beam is reflected by the first reflective surface. A fourth reflective surface is disposed within the chamber and is obliquely oriented with respect to the incoming path of the beam. The fourth reflective surface directs the beam through the second opening after the beam has been reflected a plurality of times between the second and third reflective surfaces.

Abstract: Light-reflective concave portions are disposed on the surface of a substrate. The concave portions have a first and second vertical section perpendicular to each other. The first vertical section has an internal shape defined by a first curve and a second curve, the first curve extending from one point on the peripheral edge of the concave portion to the deepest point of the concave portion, and the second curve extending continuously from the first curve and from the deepest point of the concave portion to another point on the peripheral edge of the concave portion. The average of the absolute value of an inclination angle of the first curve is larger than that of the second curve relative to the substrate surface. The second vertical section has an internal shape defined by a shallow curve and deep curves formed at both sides of the shallow curve.

Abstract: The invention comprises an afocal lens and mirror assembly comprising an objective lens which gathers light from an object and a field lens which transmits light to a driver's eye to provide an image having sufficient brightness, clarity, and accuracy. The light passing between the objective lens and the field lens is conditioned through an assembly of lenses and reflective elements to produce the image.

Abstract: A fusion monitor system for vehicles which includes a sideview mirror unit having an object lens and an eye lens at both sides of a housing which is disposed backwardly from inside and outside of the vehicle and a movable reflecting mirror between two lenses to form an afocal optical system, a movable reflecting mirror driving unit for rotating the movable reflecting mirror, a terminal holder for accepting a mobile phone, a display panel for outputting the same information as that of a display window of the mobile phone through the mirror unit. According, air resistance can be reduced, information outputted on the display window of the mobile phone can be enlarged for easy viewing and reading, and it allows hands free for user's convenience.

Abstract: There is provided a multi-mirror system for an illumination system with wavelengths ?193 nm. The multi-mirror system includes (a) an imaging system having a first mirror and a second mirror, (b) an object plane, (c) an image plane in which the imaging system forms an image of an object, and (d) an arc-shaped field in the image plane, where a radial direction in a middle of the arc-shaped field defines a scanning direction. The first and second mirrors are arranged such that an edge sharpness of the arc-shaped field is smaller than 5 mm in the scanning direction. Rays traveling from the object plane to the image plane impinge a used area of the first and second mirrors with incidence angles relative to a surface normal of the mirrors ?30° or ?60°.

Abstract: An optical device for routing a plurality of optical signals between a first port and a second port is disclosed. The optical device includes a mirror array having a plurality of reflective elements. Each optical input signal is directed by a reflective element in a direction designated by a control signal. The optical device further includes a curved mirror for receiving each directed optical signal from the respective reflective element, and for reflecting each directed optical signal to the first or second port.

Abstract: A precision optical devices having pin mounted reflector(s) are provided. The precision optical device, comprising first and second side panels, the first side panel having a hole formed therein, a first reflector comprising a first reflecting surface and a mounting pin extending from a first edge of the first reflector, the mounting pin received within the hole formed in the first side panel for mounting the first reflector between the panels at a first end of the panels, and a second reflector comprising at least a second reflecting surface, mounted between the side panels at a second end thereof in an orientation so that an incident light ray reflecting off of any of the reflecting surfaces is reflected to and off the other(s) of the reflecting surfaces in a direction substantially parallel to the incident light ray.

Abstract: An optical probe for use in accurately aligning the surfaces of microelectronic components that are to be joined together includes an optical device adapted to superimpose the images of a pair of components positioned on either side of the device. The optical device comprises an optical beam-splitter and plurality of prisms having mirror surfaces arranged so that the superposition of images takes place at the partially reflective interface within the beam-splitter. The resulting superimposed image of the die and substrate is displaced laterally from the microelectronic components so that the image is not projected onto either component.

Abstract: An optical system comprises a three-mirror anastigmat including a primary mirror, a secondary mirror, and a tertiary mirror positioned to reflect a beam path. An intermediate image is formed on the beam path at an intermediate-image location between the secondary mirror and the tertiary mirror. A negative-optical-power field mirror is positioned in the beam path at a field-mirror location subsequent to the intermediate-image location along the beam path. The field mirror reflects the intermediate image to the tertiary mirror.

Abstract: An optical deflection module adapted to generate a plurality of angular positions for at least one incident optical beam. For each optical beam, the module comprises a line containing:—a plurality of N cascading deflection elements (MD1, MD2, . . . MDI, . . . MDN) which can each take respectively P1, P2, . . . PI, . . . or PN different angular deflection configurations around at least one given axis; and—a plurality of N−1 optical conjugate elements (MCO1, MCO2, . . . MCO1, . . . , MCON-1) which are each disposed between two successive deflection elements in order to produce an object/image conjugate between the successive deflection elements.

Abstract: The invention provides a reflective optical element which has three or more reflecting surfaces by which a light flux from an object is successively reflected. In an area enclosed by each of the reflecting surfaces, the reference axis intersects at least two times and the light flux forms an intermediate image. The reference axis is a path of the light beam which passes through the center of an object surface, is then reflected by the reflecting surfaces, and passes through a center of a pupil. The reflective optical element satisfies the following condition: 4·f·tan&thgr;<ea wherein &thgr; is a maximum field angle that passes through the pupil in a plane that includes the reference axis, f is a focal length of an optical part between the pupil and an intermediate-image forming surface, and ea is a maximum optical effective diameter of the reflective optical element.

Abstract: A reflector for a precision optical device is provided. The reflector comprises a reflective surface, a back surface, a thickness between the reflective surface and the back surface defining an edge of the reflector, at least one mounting pad located along at least a portion of the edge of the reflector for adhesion to a portion of the precision optical device, and a mounting pin extending from another portion of the edge of the reflector for adhesion within a hole in the precision optical device.

Abstract: An improved lateral transfer retroreflector assembly is provided. The lateral transfer retroreflector assembly of the invention comprises a first segment comprising a mirror panel housing, a second segment comprising a roof mirror housing, and a third segment comprising an off-the-shelf connecting member between the two housings. The mirror panel housing will have mounted thereto a mirror panel. The roof mirror housing will have mounted thereto a roof mirror assembly, and the connecting member will be mounted between the mirror panel housing and the roof mirror housing. The off-the-shelf aspect of assembling the connecting allows the assembly to be built to customer specifications, thereby allowing for customized creation of lateral transfer retroreflectors, but at a time and cost savings to the customer.

Abstract: Light-reflective concave portions are disposed on the surface of a substrate. The concave portions have a first and second vertical section perpendicular to each other. The first vertical section has an internal shape defined by a first curve and a second curve, the first curve extending from one point on the peripheral edge of the concave portion to the deepest point of the concave portion, and the second curve extending continuously from the first curve and from the deepest point of the concave portion to another point on the peripheral edge of the concave portion. The average of the absolute value of an inclination angle of the first curve is larger than that of the second curve relative to the substrate surface. The second vertical section has an internal shape defined by a shallow curve and deep curves formed at both sides of the shallow curve.

Abstract: An optical pathway selector is provided having a first direction selector, a second direction selector, and an actuator. The first direction selector is comprised of a substantially planar member having alternating reflecting and transparent portions. The first direction selector is disposed for rotation on an axle with the substantially planar member positioned askew to a first optical axis. The second direction selector has a configuration similar to that of the first direction selector and is disposed along the axle substantially parallel to the first direction selector. Additional direction selectors can be employed in a similar manner. A motor is connected to the axle for rotating the direction selectors. Alternatively, a motor moves the direction selector along a linear pathway in and out of the pathway of different light beams. The optical pathway selector is used to reflect a beam of light from the first optical axis to alternative optical axes or vice-versa.

Abstract: An optical system capable of providing a magnification which can be varied comprises a pair of ellipsoidal mirrors [(20, 21)]which are so mounted and arranged that the focus for radiation reflected from one mirror corresponds substantially with the input focus for the other mirror. The mirrors are preferably mounted so that they are pivotable.

Abstract: A retroreflector has three mutually-orthogonal reflective surfaces arranged around an optical axis. The reflective surfaces stop short of the optical axis to provide a central region of the retroreflector which transmits incident light and a peripheral region of the retroreflector which retroreflects incident light. When the reflector is used in a Jamin-type interferometer with another reflector, this enables the interferometer to be used for measuring displacement between the reflectors. In the interferometer, a projected beam is disposed between a pair of return beams and/or one of the return beams is disposed between a pair of the projected beams. This enables a first contiguous area of a face of a beam splitter to be provided with a phase-shifting coating to produce a phase quadrature relationship between a pair of interferogram beams. This simplifies the masking required when applying the coating.

Abstract: A solar energy concentrator (1) is formed in the shape of a spiral horn, so that solar energy incident over a wide range of incident angles on the mouth (2) of the horn is concentrated by multiple reflections from inner walls (5) of the horn to emerge from an exit aperture (3) at the center of the horn. Solar energy emerging from the collector may be distributed by light pipes (40) to illuminate a building or may be transmitted to a solar energy conversion chamber (50) having a small entry aperture (51). The entry aperture (51) acts as black body absorbing all solar energy incident upon it and the solar energy may be converted within the chamber (50) either by photovoltaic cells and/or by heat absorbing media.

Abstract: A reflection type magnification projection optical system includes five light-reflecting mirrors arranged from an object side to an image side in a sequence of a concave mirror (M1), a convex mirror (M2), a concave mirror (M3), a convex mirror (M4), and a concave mirror (M5) such that those mirrors basically form a coaxial system, and forming no intermediate image, and wherein an object point and an image point are respectively on opposite sides across an optical axis, and the object point and the image point are kept 400˜1500 mm apart with respect to a direction orthogonal to the optical axis.

Abstract: A concave mirror optical system for a scanner and a method for compensating image distortion. In this invention, the more expensive lens assembly in a conventional optical system is replaced by a concave mirror made from simple low-cost material so that production cost and chromatic dispersion are reduced. Moreover, different magnifications can be obtained due to a difference in focusing power of the concave mirror along XY axis direction.

Abstract: An optical element formed from a transparent optical material includes two refraction surfaces, a first reflection surface group having a plurality of internal reflection surfaces arrayed in a predetermined direction, a second reflection surface group opposing the first reflection surface group and having at least one internal reflection surface and two side surfaces opposing each other in parallel to the predetermined direction. Light incident from one of the refraction surfaces is alternately reflected by the internal reflection surfaces of the first reflection surface group and the internal reflection surface of the second reflection surface group and guided to the other refraction surface.

Abstract: A reflecting type of zoom optical system comprises a plurality of optical elements each of which includes a transparent body and two refracting surfaces and a plurality of reflecting surfaces formed on the transparent body and is arranged so that a light beam enters the transparent body from one of the two refracting surfaces, repeatedly undergoes reflection by the plurality of reflecting surfaces, and exits from the other of the two refracting surfaces, and/or a plurality of optical elements on each of which a plurality of reflecting surfaces made from surface reflecting mirrors are integrally formed, and each of which is arranged so that an entering light beam repeatedly undergoes reflection by the plurality of reflecting surfaces and exits from the optical element.

Abstract: A bright reflection type projection optical system is used for projecting onto a screen under magnification a luminous flux carrying image information from a light valve driven by an image signal, while favorably correcting aberration. The reflection type projection optical system comprises, successively from the enlargement side, a first mirror having a positive power, a second mirror having a negative power, and a third mirror having a positive power.

Abstract: A reading optical system that forms the image of the original document on a one-dimensional imaging element, such system comprising multiple reflective surfaces only, wherein at least one of such surfaces is a free-form surface that has a symmetrical surface relative to the main scanning direction and no symmetrical surface relative to the sub scanning direction. Where the light beam that passes through the center of the original document and the center of the aperture is deemed the axial main light beam, the path of the axial main light beam that strikes the first reflective surface extends along the Z-axis, the length of the one-dimensional imaging element extends along the Y-axis, and the X-axis extends perpendicular to the Y-axis and the Z-axis, each reflective surface is arranged such that it is tilted relative to the Y-axis.

Abstract: An optical, image producing device of the Camera Lucidas type is provided wherein the panel on which the optical image is superimposed may be supported at different angles of inclination on a base, to which a mirror assembly carrying column is rigidly attached, so that the inclination of the panel can be adjusted allowing the device to be used tilted to observe an object at different elevations. The column has a viewing aperture which is wide enough for an image to be viewed simultaneously by both eyes to give a panoramic view.

Abstract: A modularized light-guiding apparatus and manufacturing method, which may make the light of a light source proceed at least twice light reflections of predetermined directions. The light-guiding apparatus includes a plurality of modularized reflection elements, which may be differentiated to several different types of reflection element. Each type of each reflection element all has substantially same adjoining device and edge size for providing to be adjoined and piled-up with another reflection element. But, the reflection element of different type individually has different number of reflection plane for providing the light to proceed different times of light reflection. It may determined the light reflection times and light-path length for the light-guiding apparatus, by choosing several different types of reflection element among plural reflection elements to proceed the piling-up for the light-guiding apparatus.

Abstract: This invention has as its object to prevent deterioration of optical performance by suppressing the respective reflection surfaces from being decentered relative to each other in an optical element formed by placing a plurality of reflection surfaces having curvatures at neighboring positions. In order to achieve this object, an optical element according to this invention has a first reflection surface block formed by placing a plurality of reflection surfaces having curvatures at neighboring positions, and a second reflection surface block which faces the first reflection surface block, and is formed by placing one or more reflection surfaces at neighboring positions, and the first and second reflection surface blocks are formed by a metal mold.

Abstract: A reflection type image forming optical system and a projector are compact with wide view angle, in expensive and having uniform illumination intensity. The reflection type image forming optical system includes a first reflection mirror having a rotation symmetric aspheric shape concave reflection surface directed to an image forming surface arranged an image forming element thereon, a second reflection mirror having a rotation symmetric aspheric shape convex reflection surface directed toward a flux of light from the first reflection mirror, a third reflection mirror having a rotation symmetric aspheric shape concave reflection surface directed toward a flux of light from the second reflection mirror and a fourth reflection mirror having a rotation symmetric aspheric shape convex reflection surface directed toward a flux of light from the third reflection mirror. The first, second, third and fourth reflection mirrors form a telecentric optical system.

Abstract: A derotation mirror system for a common-optical-path panoramic stabilized periscope. The derotation system has a first surface-reflecting mirror, a second surface-reflecting mirror and a third surface-reflecting mirror. Through subsequent reflection of light from the surface of the first surface-reflecting mirror, the second surface-reflecting mirror, the third surface-reflecting mirror and a rotation of the entire derotation mirror system with respect to the Z-axis, the derotation is achieved. Since this invention only requires three reflections, the derotation system allows the lights with various wavebands (such as visible light, infrared light and laser beam). In addition, the derotation system manages to constrain the propagation of the output image vector and the output image vector along the same Z-axis line.

Abstract: An optical path folding apparatus of the present invention receives an incident light and reflects a reflection light on a lens set. The optical path folding apparatus comprises a first portion receiving the incident light and reflecting a first light beam, a second portion receiving the first light beam and reflecting a second light beam, a third portion receiving the second light beam and reflecting a third light beam, a fourth portion receiving the third light beam and reflecting a fourth light beam, a fifth portion receiving the fourth light beam and reflecting a fifth light beam, and a sixth portion receiving the fifth light beam and reflecting a reflection light on the lens set. In a preferred embodiment, the first portion and the fifth portion are coplanar on a first mirror, while the second portion, the fourth portion and the sixth portion are coplanar on a second mirror.

Abstract: A reduction objective, a projection exposure apparatus with a reduction objective, and a method of use thereof are disclosed. The reduction objective has a first set of multilayer mirrors in centered arrangement with respect to a first optical axis, a second set of multilayer mirrors in centered arrangement with respect to a second optical axis, and an additional mirror disposed at grazing incidence, such that said additional mirror defines an angle between the first optical axis and said second optical axis. The reduction objective has an imaging reduction scale of approximately 4× for use in soft X-ray, i.e.

Abstract: A reading optical system that forms the image of the original document on a one-dimensional imaging element, such system comprising multiple reflective surfaces only, wherein at least one of such surfaces is a free-form surface that has a symmetrical surface relative to the main scanning direction and no symmetrical surface relative to the sub scanning direction. Where the light beam that passes through the center of the original document and the center of the aperture is deemed the axial main light beam, the path of the axial main light beam that strikes the first reflective surface extends along the Z-axis, the length of the one-dimensional imaging element extends along the Y-axis, and the X-axis extends perpendicular to the Y-axis and the Z-axis, each reflective surface is arranged such that it is tilted relative to the Y-axis.

Abstract: The invention provides a reflective optical element which has three or more reflecting surfaces by which a light flux from an object is successively reflected. In an area enclosed by each of the reflecting surfaces, the reference axis intersects at least two times and the light flux forms an intermediate image. The reference axis is a path of the light beam which passes through the center of an object surface, is then reflected by the reflecting surfaces, and passes through a center of a pupil.

Abstract: A nonimaging light concentrator system including a primary collector of light, an optical mixer disposed near the focal zone for collecting light from the primary collector, the optical mixer having a transparent entrance aperture, an internally reflective housing for substantially total internal reflection of light, a transparent exit aperture and an array of photovoltaic cells disposed near the transparent exit aperture.

Abstract: When n is taken as integers of 2 or more, n reflecting systems are constituted by providing reflecting mirrors on opposite (two) side surfaces in 2n side surfaces of a transparent body having the shape of a 2n-sided prism. The n reflecting systems are provided on each pair of opposite side surfaces, and images of an object are formed using each of the n reflecting systems.

Abstract: A cube corner laser beam retroreflector apparatus for a beam path external to a laser reduces the effect of small deviations in flatness of optical carriage mounting elements and/or linear ways that pitch, yaw and roll the carried retroreflector apparatus. Small changes in pitch, yaw and roll are converted to a small translation in position of the beam reflected from the apparatus. Since the reflected beam remains parallel to the incoming beam, the length of the beam path does not magnify such small deviations in position and system pointing stability is greatly improved. The cube corner retroreflector comprises a welded frame and three mirror holders, the welded frame consisting of plasma, laser or abrasive water jet cut tabbed and slotted flat plates welded together. Each mirror holder is adjustably attached to the welded frame and houses a removable mirror.