An optical assembly is manufactured by combining a first optical component with a second optical component. The optical components each comprise respective optical surfaces and alignment structures. The first optical surface is aligned with respect to the second optical surface by a connection between the alignment structures and their predefined relative positions with respect to the optical surfaces. The relative positions are determined by a high-accuracy manufacturing process such as diamond turning wherein, for each optical component, a respective alignment structure is manufactured together with a respect optical surface from a single work piece.

Filter wheel assemblies with a single actuation point to control positioning of front and rear optical filter elements simultaneously and to provide high channel density with a plurality of selectable optical filter pairs. A filter wheel assembly may include a plurality of optical filter element pairs arranged around a common axis, wherein each of the plurality of optical filter element pairs includes a first filter element and a complementary filter element, wherein each first filter element and each complementary filter element has a surface having a normal component directed toward an inner portion of the filter wheel assembly.

An eye-mounted device includes a contact lens and an embedded imaging system. The front aperture of the imaging system faces away from the user's eye so that the image sensor in the imaging system detects imagery of a user's external environment. The optics for the imaging system has a folded optical path, which is advantageous for fitting the imaging system into the limited space within the contact lens. In one design, the optics for the imaging system is based on a two mirror design, with a concave mirror followed by a convex mirror.

A method for adjusting the magnification scale of an optical imaging device for exposing or inspecting substrates is provided. The optical imaging device includes a first optical element group, which includes a plurality of first optical elements in an imaging beam path. The method includes replacing optical elements of the first optical element group in the imaging beam path by optical elements of a second optical element group for the purposes of adjusting the magnification scale. The first optical element group includes two reflecting optical elements with first optical parameters, which define a first Petzval sum. The second optical element group includes two reflecting optical elements with second optical parameters, which define a second Petzval sum. The value of the first Petzval sum is at least substantially identical to the value of the second Petzval sum.

Filter wheel assemblies with a single actuation point to control positioning of front and rear optical filter elements simultaneously and to provide high channel density with a plurality of selectable optical filter pairs. A filter wheel assembly may include a plurality of optical filter element pairs arranged around a common axis, wherein each of the plurality of optical filter element pairs includes a first filter element and a complementary filter element, wherein each first filter element and each complementary filter element has a surface having a normal component directed toward an inner portion of the filter wheel assembly.

A variety of femtoprojector optical systems are described. Each of them can be made small enough to fit in a contact lens using plastic injection molding, diamond turning, photolithography and etching, or other techniques. Most of the systems include a solid transparent substrate with a curved primary mirror formed on one face, a secondary mirror formed on the opposite face, and an annular exit aperture located axially between the two mirrors The designs use light blocking, light-redirecting, absorbing coatings or other types of baffle structures to reduce stray light.

A cloaking device includes an object-side, an image-side and an apex axis extending from the object-side to the image-side. An object-side cloaking region (CR) planar reflection boundary having an outward facing mirror surface and an inward facing surface, and an image-side CR planar reflection boundary having an outward facing mirror surface and an inward facing surface, are included. A cloaking region is bounded by inward facing surfaces of the object-side CR planar reflection boundary and the image-side CR planar reflection boundary. At least one exterior curved reflection boundary with an inward facing mirror surface is spaced apart from the object-side CR planar reflection boundary and the image-side CR planar reflection boundary. A centrally positioned planar reflection boundary with an outward facing mirror surface is positioned between the objects-side and image-side CR planar reflection boundaries and faces the inward facing mirror surface of the at least one exterior curved reflection boundary.

There is provided a projection optical system that projects an image of an object onto an image plane. The projection optical system includes an imaging optical system including a first concave mirror, a convex mirror, and a second concave mirror; an optical member having a first reflecting surface and a second reflecting surface each redirecting an optical path; and a supporting member that supports the convex mirror. The first reflecting surface, the first concave mirror, the convex mirror, the second concave mirror, and the second reflecting surface are provided in that order in a direction of travel of light from an object plane. The optical member has a through hole having an opening on a side facing the convex mirror. The supporting member extends through the through hole and from the opening to the convex mirror.

A variety of femtoprojector optical systems are described. Each of them can be made small enough to fit in a contact lens using plastic injection molding, diamond turning, photolithography and etching, or other techniques. Most of the systems include a solid transparent substrate with a curved primary mirror formed on one face, a secondary mirror formed on the opposite face, and an annular exit aperture located axially between the two mirrors The designs use light blocking, light-redirecting, absorbing coatings or other types of baffle structures to reduce stray light.

The present invention relates to a compact, lightweight, cost-efficient ultraviolet-visible-far infrared (UV-VIS-IR) telescope system, covering the 300 nm to 2500 nm (0.3 ?m to 2.5 ?m) spectral range, based on a fast focal-ratio, reflective optics design, and an optical coupling interface appropriate for COTS spectrometers, commensurate with about 1U-2U CubeSat payload volume.