A projection system and calibration method therefor relate to a light source configured to emit a light in response to an image data, an illumination optical system configured to steer the light, the illumination optical system including a first minor and a second minor, a digital micromirror device (DMD) including a plurality of micromirrors respectively configured to reflect the steered light to a filter as on-state light or to reflect the steered light as off-state light to a light dump; determining a deviation between an actual angle of orientation and an expected angle of orientation of the DMD; calculating a first amount of angle adjustment corresponding to the first minor and a second amount of angle adjustment corresponding to the second mirror; and actuating the first mirror according to the first amount and the second mirror according to the second amount.

An optical element adjustment device includes a casing base, an optical element, a bearing element, and a first adjustment module. The optical element is movably disposed in the casing base. The bearing element includes an outer frame bearing the optical element and a shaft portion protruding from the outer frame and penetrating from the casing base. The first adjustment module is disposed on the shaft portion. A screw shank is sleeved on the shaft portion and penetrates from the casing base. The first adjustment element is screwed to the screw shank and abuts against the casing base. A limiting element protrudes from a side surface of the shaft portion and is located next to the screw shank. The first elastic element is disposed between the screw shank and the outer frame, such that the screw shank leans closely to the limiting element.

A fiber inspection system for inspecting optical-fiber endfaces of a multiple-fiber connector is provided that includes a housing structure, a mating interface fixed relative to the housing structure for interfacing with the multiple-fiber connector, and an imaging assembly. The imaging assembly is enclosed in the housing structure and defines an inspection plane and an image plane, at least a plurality of the optical-fiber endfaces being disposed on the inspection plane, to within a focusing range, when the multiple-fiber connector is mated to the mating interface. The imaging assembly also defines an imaging axis between an inspection point on the inspection plane and a detection point on the image plane, and includes an alignment module disposed between the inspection plane and the image plane and controllable to move the inspection point across the inspection plane for selectively inspecting one or more of the optical-fiber endfaces.

A system for providing two parallel light beams spaced-apart a selectable distance, the system including: a first beam splitter configured for reflecting a light beam from a light source to create a first datum light beam, the first beam splitter is fixedly attached to a base; a second beam splitter configured for reflecting a transmitted light beam from the light beam from the light source to create a second datum light beam, a third beam splitter configured for reflecting a transmitted light beam from the light beam from the light source to create a third datum light beam, a fourth beam reflecting device configured for reflecting a transmitted light beam from the light beam from the light source to create a fourth light beam. Each of the second, third beam splitters and fourth beam reflecting device is configured to be slidingly attached to the base.

A method and apparatus for mounting optical components is described. The apparatus (1) is suitable for mounting multiple optical components (2) and comprises a baseplate (3) having opposing first (4) and second (5) surfaces. Recesses or apertures (7) are formed within the baseplate and are located upon the first or second surfaces so as to define thermally activated optic mounting areas. Pillars (13) are then located within the thermally activated optic mounting areas and these provide a means for attaching the optical component to the baseplate (3). The employment of the recesses or apertures act to significantly reduce the thermal conduction throughout the baseplate. As a result preferential heating can be provided to the one or more thermally activated optic mounting areas while maintaining the baseplate with a desired mechanical strength. The optical mounting apparatus exhibits a high thermal stability thus making the apparatus ideally suited for use within commercial optical system.

An optical imaging lens including, in order from an object side to an image side, an aperture, a first lens, a second lens, a third lens, a fourth lens and a fifth lens, wherein the first lens has positive refractive power and includes a convex image-side surface; the second lens has negative refractive power and includes a convex object-side surface and a concave image-side surface; the third lens has positive refractive power and is biconvex; the fourth lens has positive refractive power and includes a concave object-side surface and a convex image-side surface; the fifth lens has negative refractive power and includes a convex object-side surface and a concave image-side surface. The object-side and image-side surfaces of the third lens, the fourth lens, and the fifth lens are aspheric. The optical imaging lens includes a total of five elements.

A reflective beam former for changing a diameter of a collimated light beam. A first mirror surface of a first curvature type, a second mirror surface and a third mirror surface are in a beam path; the shapes of the surfaces cause a collimated light beam entering the beam former via a first or third mirror surface to leave via the third or first mirror surface, respectively. The beam former includes several third, curved mirror surfaces of a second, different curvature type, one type being convex, the other concave. The second mirror surface is a plane mirror surface with an axis perpendicular to the plane mirror surface, and is in the beam path between the first and one selected from the several third mirror surfaces such that the surfaces are confocal to each other. The beam former includes a selector for selecting one of the several third curved mirror surfaces.

The invention relates to a mirror assembly (1) for producing a plurality of beam bundles (K1, K2, . . . Kn) from the beam of a light source (L), wherein the plurality of beam bundles comprises at least one first beam bundle (K1) having a first main beam direction (SR1), a second beam bundle (K2) having a second main beam direction (SR2), and preferably further beam bundles (K3 . . . Kn) having further main beam directions, which mirror assembly comprises the following features: a first mirror segment (1a) having a first focal point (F1), which first mirror segment converts a first partial region of the beam (S1) of the light source into the first beam bundle (K1), a second mirror segment (1b) having a second focal point (F2), which second mirror segment converts a second partial region of the beam (S2) of the light source into the second beam bundle (K2), and preferably further mirror segments (1c) having further focal points (F3 . . . Fn), which further mirror segments convert further partial regions of the beam of the light source into further beam bundles (K3 . . . Kn), wherein the back side of the mirror segments has a curvature having the radius R_s, which curvature is concentric to the light source.

To improve alignment accuracy of an optical element. An alignment device includes an optical element, a base portion that holds the optical element and is supported in a state movable in an X-direction and a Y-direction intersecting with the X-direction, a mechanical driving unit driven by a pressure of a fluid, a member in contact with the base portion pushed by the mechanical driving unit, a stage portion that holds the member and is supported in a state movable in the Y-direction, the mechanical driving unit driven by a pressure of a fluid, and a member in contact with the stage portion pushed by the mechanical driving unit. The optical element has a position: adjusted by a balance between the pushing force by the mechanical driving unit and an elastomeric force in which at least one of the base portion and the member elastically deforms in the X-direction; and adjusted by a balance between the pushing force by the mechanical driving unit and an elastomeric force in which at least one of the stage portion and the member elastically deforms in the Y-direction.

An optical element adjusting apparatus configured to support an optical element includes an adjusting base, a fixed base and locking elements. The adjusting base includes a first through hole disposed on a center of gravity of the adjusting base, a second through hole and a third through hole. An extension direction of a first straight line passing through the first through hole and the second through hole is different from an extension direction of a second straight line passing through the first through hole and the third through hole. The fixed base includes coupling holes corresponding to the first, second, third through holes. The locking elements pass though the first, second, third through holes respectively and are coupled to the coupling holes to couple the adjusting base to the fixed base. The adjusting base includes a support side away from the fixed base to support the optical element.