Coated surfaces arranged in a stack assume a periodic formation having a sequence of segments including a first segment. The first segment has first, second, and third coated surfaces, and is repeated a set number of times to form the periodic formation. The stack is sliced to form a slice having two major external surfaces and adjacent sections each having coated surfaces from one segment between the two major external surfaces. The slice is cut to form at least one substrate from each section. Each substrate has two major surfaces and coated surfaces from a single segment of the periodic formation between the two major surfaces. In certain embodiments, the first coated surface reflects a first light color, the second coated surface transmits the first light color and reflects a second light color, and the third surface reflects a third light color and transmits the first and second light colors.

A combination mirror and media display device assembly includes a mirror platform. The mirror platform has a media display device viewing area and a reflective area. A reflectivity of the media display device viewing area is less than a reflectivity of the reflective area. The assembly includes a mounting bracket. The mounting bracket is coupled to the mirror platform. The mounting bracket is open on one side and the opening in the mounting bracket is configured to accept a media display device. A method to place a media display device within a mirror platform assembly includes inserting a media display device through an opening in a mounting bracket, wherein a mirror platform is attached to the mounting bracket and the mirror platform has a media display device viewing area. The method includes aligning the media display device with the media display device viewing area during the inserting and coupling the media display device to the mounting bracket, wherein the media display device is removably coupled to the mounting bracket.

A method for providing spectral beam combining (SBC) including generating a plurality seed beams each having a central wavelength and a low fill factor profile, where the wavelength of all of the seed beams is different; amplifying the seed beams; causing the amplified beams to expand as they propagate so as to be converted from the low fill factor profile to a high fill factor profile where the high fill factor profile tapers to a lower value at a perimeter of each beam; causing a wavefront of the converted beams to flatten to provide a plurality of adjacent SBC beams having different wavelengths with minimal overlap and a minimal gap between the beams; collimating the SBC beams; and directing the collimated SBC beams onto an SBC element that spatially diffracts the individual beam wavelengths and directing the beams in the same direction as a combined output beam.

A laser range finder and method for adjusting, comprising a beam source, a photodetector, at least one beam shaping optic, an optic bracket, a circuit board, a beam splitting optic and a connecting device; the beam source comprises a first electro-optical component for emitting a laser beam, the photodetector comprises a second electro-optical component for receiving a received beam reflected and/or scattered by a target object along an optical axis, the beam shaping optic is configured to form a laser beam and/or a receiving beam, the optic bracket comprises a first accommodating seat for fixing the first electro-optical component and a second accommodating seat for fixing the at least one beam shaping optic, the circuit board comprises an another seat for fixing the second electro-optical component, the connecting device is configured to connect the optic bracket with the circuit board; the beam splitting optic is arranged on an adjustment bracket.

The present disclosure provides an optical component array and method of making an optical component array that can include a plurality of optical components useful for projection devices or other optical devices. The optical component array can be fabricated such that individual optical components having several elements can be assembled in a massively parallel manner and then singulated as individual optical components, and can result in a large reduction in manufacturing cost.

In various embodiments, pointing errors in a non-wavelength-beam-combining dimension of a laser system are at least partially alleviated via staircased collimation lenses.

Apparatus and method are disclosed for co-aligning a number of laterally displaced radiation beams from respective radiation source outputs, each beam having a respective waveband. The apparatus comprises a collimating element for receiving each of said radiation beams with respective lateral displacements and a combining element for receiving each of said radiation beams passed by said collimating element. The apparatus further comprises a radiation source mount for positioning the radiation source outputs relative to the collimating element. The method comprises longitudinally positioning the radiation source outputs upon the mount, relative to the collimating element, in dependence upon the waveband of each beam, to cause the radiation beams passed by the combining element to be co-aligned.

Disclosed are transparent energy relay waveguide systems for the superimposition of holographic opacity modulation states for holographic, light field, virtual, augmented and mixed reality applications. The light field system may comprise one or more energy waveguide relay systems with one or more energy modulation elements, each energy modulation element configured to modulate energy passing therethrough, whereby the energy passing therethrough may be directed according to 4D plenoptic functions or inverses thereof.

An optical substrate has a structured surface that enhances brightness and reduces moire effect. The optical substrate has a three-dimensionally varying, structured light output surface that comprises an irregular prismatic structure. The irregular prismatic structure may be viewed as comprising longitudinal prism blocks or rows thereof, arranged laterally defining peaks and valleys. Adjacent peaks, adjacent valleys, and/or adjacent peak and valley may be parallel or non-parallel, in an orderly, semi-orderly, random, or quasi-random manner. The lateral adjacent peaks, adjacent valleys, and/or adjacent peak and valley are not parallel. The adjacent irregular prism blocks may be irregular longitudinal sections having the same length, or random or quasi-random irregular sections having different lengths. The facets of each prism block may be flat, or curved (convexly and/or concavely).

Direct-bonded lamination for improved image clarity in optical devices is provided. An example process planarizes and plasma-activates optical surfaces to be laminated together, then forms direct bonds between the two surfaces without an adhesive or adhesive layer. This process provides improved optics with higher image brightness, less light scattering, better resolution, and higher image fidelity. The direct bonds also provide a refractory interface tolerant of much higher temperatures than conventional optical adhesives. The example process can be used to produce many types of improved optical components, such as improved laminated lenses, mirrors, beam splitters, collimators, prism systems, optical conduits, and mirrored waveguides for smartglasses and head-up displays (HUDs), which provide better image quality and elimination of the dark visual lines that are apparent to a human viewer when conventional adhesives are used in conventional lamination.