A nanocomposite-ink refractive gradient optic with variable focus optic comprising a first optical-element, a second optical-element, each the optical-elements comprised of a cured nanocomposite-ink wherein the first and second optical-element have a cubic volumetric gradient complex optical index such that when arranged in tandem along an optical axis the optical power varies based on linear translation with respect to another.

An optical system includes a compound lens that includes a first lens and a second lens. The first lens is made of a resin, and the second lens is made of glass. In a case where a maximum value of a thickness of the first lens is denoted by A [mm] and a minimum value of the thickness of the first lens is denoted by B [mm], the optical system satisfies Conditional Expressions (1) and (2).

[00001]$\begin{array}{cc}A/B10& \left(1\right)\end{array}$$\begin{array}{cc}A3\mathrm{mm}& \left(2\right)\end{array}$

In a case where an amount of plastic deformation of the resin in a state where an indenter is pressed into the resin at a loading rate of 200 mN/10 sec at an environmental temperature of 25 C. is denoted by x [m], the resin satisfies Conditional Expression (3).

[00002]$\begin{array}{cc}1.mx4.m& \left(3\right)\end{array}$

The present invention relates to a method for manufacturing an optical element (100) having at least one functional region using a 3D-printer, comprising the steps: forming a three-dimensional structure (50) of the optical element (100) using a 3D-printer such that the three-dimensional structure (100) has at least one microfluidic cavity (4) for receiving a functional substance (6); and filling the at least one microfluidic cavity (4) with the functional substance (6) for forming the at least one functional region.

In addition, the invention relates to a device for manufacturing an optical element (100) as well as a use of the device.

A manufacturing apparatus for a composite optical element includes a first cavity portion which molds a first optical element portion partly having a first optical function surface with the first molding material, and a second cavity portion which molds a second optical element portion that is provided on the first optical element portion to cover the first optical function surface with a second molding material, and integrates the second optical element portion with the first optical element portion, whereby mold the composite optical element. The manufacturing apparatus includes a discharge opening portion in which a discharge direction of the second molding material from a supply path portion to the second cavity portion is along the first optical function surface.

A hybrid compound lens includes a substrate lens and a resin lens. The substrate lens has a non-planar substrate surface surrounded by a flange having a flange surface bordering the non-planar substrate surface and forming an obtuse angle therewith. The resin lens has a non-planar resin surface adjoining the substrate lens along the non-planar substrate surface. A lens wafer includes a substrate wafer and resin lenses. The substrate wafer has a top surface having non-planar surface features each bordered by a planar region of the top surface and forming an obtuse angle therewith. Each resin lens has a non-planar resin surface adjoining the substrate wafer along a non-planar surface feature. A method for fabricating a wafer-level hybrid compound lens includes depositing a resin portion on a non-planar feature of a side of a substrate. The method also includes forming the resin portion into a lens on the non-planar feature.

A headset for virtual reality applications includes an optical element configured to modify light from an electronic display in the headset and to direct the modified light to a user. The optical element may include a Fresnel lens secured to a lens by securing the Fresnel lens to a mold and inserting a casting material into the mold so the casting material forms the lens and a portion of the casting material exists on and past an edge of the Fresnel lens. This encases the edge of the Fresnel lens in the casting material, securing the Fresnel lens to the lens.

Fabricating optical devices can include mounting a plurality of singulated lens systems over a substrate, adjusting a thickness of the substrate below at least some of the lens systems to provide respective focal length corrections for the lens systems, and subsequently separating the substrate into a plurality of optical modules, each of which includes one of the lens systems mounted over a portion of the substrate. Adjusting a thickness of the substrate can include, for example, micro-machining the substrate to form respective holes below at least some of the lens systems or adding one or more layers below at least some of the lens systems so as to correct for variations in the focal lengths of the lens systems.

The invention relates to a method for manufacturing an ophthalmic lens having at least one optical function, comprising the step of providing a starting optical system of the lens, having a basic optical function and the step of additively manufacturing an additional optical element of the lens, by deposition of multiple predetermined bulking components made of at least one material having a predetermined refractive index, directly onto the front surface and/or the rear surface of the starting optical system; wherein the additive manufacturing step comprises the step of determining a manufacturing guideline for the additional optical element on the basis of the characteristics of said at least one optical function to be provided to the lens, the characteristics of said at least one basic optical function, the geometric characteristics of the starting optical system, and the predetermined refractive index of the material.

Systems and methods according to one or more embodiments are provided for annealing a chalcogenide lens at an elevated temperature to accelerate release of internal stress within the chalcogenide lens caused during a molding process that formed the chalcogenide lens. In particular, the annealing process includes gradually heating the chalcogenide lens to a dwell temperature, maintaining the chalcogenide lens at the dwell temperature for a predetermined period of time, and gradually cooling the chalcogenide lens from the dwell temperature. The annealing process stabilizes the shape, the effective focal length, and/or the modulation transfer function of the chalcogenide lens. Associated optical assemblies and infrared imaging devices are also described.

A compound lens produced by heating and pressing a semi-cured product of a curable resin composition containing a (meth)acrylate monomer, a non-conjugated vinylidene group-containing compound, and a photo-radical initiator and a transparent substrate arranged so as to be in contact with the semi-cured product in a state in which a molding die is filled with the semi-cured product and the transparent substrate, and obtaining a cured product by allowing the semi-cured product to be thermally polymerized, exhibits an excellent transfer property, a small number of bubble mixtures, and excellent heat resistance and crack resistance.