Methods, systems, devices, and apparatuses are described. Light output by a light source may be transformed into an annular shape (e.g., a spatial distribution of the light may be modified to have an annular shape) to cure an adhesive material having a similar annular shape. For example, a system may include a light source emitting light (e.g., ultraviolet (UV) light) having an angular distribution and a spatial distribution. An optical system may modify a shape of the spatial distribution into an annular shape, and the light having the annular shape may be focused on an adhesive material to cure the adhesive material. In some examples, the adhesive material may be positioned between an optical element and a structural component, and the focused light in the annular shape may cure the adhesive material while simultaneously avoiding one or more other optical components or structures.

A system for retaining an optical member about a mount can comprise a mount, an optical member having a first end and a second end, a primary retention system operable to secure the second end of the optical member to the mount, and a secondary retention system operable to secure the second end of the optical member to the mount. The secondary retention system can comprise a mount retention groove formed in the mount, an optical member retention groove formed in the optical member, the mount retention groove in the mount and the optical member retention groove in the optical member forming a retention channel upon the optical member being secured to the mount via the primary retention system, and a retention wire disposed within the retention channel. The secondary retention system activates to cause the retention wire to engage the mount retention groove of the mount and the optical member retention groove of the optical member upon movement of the optical member and at least partial failure of the primary retention system to retain the optical mount securely coupled to the mount.

An optical module includes a first bearer and a second bearer. The first bearer includes a first bearing portion and an inclined plane, the first bearing portion is configured to carry a first optical element, and the inclined plane is disposed on a peripheral edge of a first end surface of the first bearing portion. The second bearer includes a second bearing portion and a protruding portion, the second bearing portion is configured to carry a second optical element, a second end surface of the second bearing portion faces the first end surface, and the protruding portion extends from the second end surface to the first bearing portion and is configured to contact the inclined plane. When the protruding portion contacts the inclined plane, the inclined plane does not expose the protruding portion in a direction from the first bearing portion to the second bearing portion.

An optical apparatus includes a first base and a second base, an optical element held by at least one of the first and second bases, and an adhesive configured to adhere the first and second bases to each other. The first base further includes a first recessed portion into which the second base is inserted, a first contact portion contacting the second base, and a groove portion configured to allow at least a part of the adhesive to enter therein. The second base includes a second contact portion configured to contact the first contact portion.

Adaptable lens assemblies, optoelectronic components, and associated methods of manufacturing are provided. An example optoelectronic component includes a printed circuit board (PCB) and an adaptable lens assembly. The adaptable lens assembly includes a lens packaging structure supporting an optical lens at a focal distance and a lens support structure. The lens support structure defines a first side configured to support the lens packaging structure and maintain the focal distance and a second side removably attached to the PCB. The attachment between the second side of the lens support structure and the PCB is configured to enable selective attachment and detachment of the lens support structure and lens packaging structure supported thereon without causing damage to the PCB.

An imaging lens module includes a plastic barrel, an optical lens assembly and a glue material. The plastic barrel includes an outer object-end surface, an outer image-end surface and an inner tube surface. The inner tube surface connects the outer object-end surface and the outer image-end surface, and includes a plurality of parallel inner surfaces. A plurality of stripe structures are disposed on and protruded from at least one of the parallel inner surfaces, wherein the stripe structures are regularly arranged along a circumferential direction of the parallel inner surface. The optical lens assembly includes a plurality of optical elements disposed in the plastic barrel and arranged along the optical axis, wherein an outer annular surface of at least one of the optical elements is disposed correspondingly to the stripe structures. The glue material is applied among the outer annular surface and the stripe structures.

A multi-group lens assembly includes a plurality of lens group units and at least one assembly structure. The assembly structure is for assembling two adjacent lens group units. Lenses in the lens group units are made of any two or three of a glass material, a resin material, and a glass-resin composite material. Alternatively, the lenses are made of only the glass-resin composite material. The lenses can be assembled and adjusted easily and conveniently and have high pixel densities and small TTLs, thereby improving user experience.

A camera module is provided. A camera module according to an aspect of the present invention comprises: a lens barrel accommodating a lens; a lens holder accommodating the lens barrel; an image sensor disposed under the lens barrel; and a printed circuit board having an image sensor mounted thereon and coupled to the lens holder, wherein the lens barrel and the lens holder are primarily coupled to each other in a state where an optical axis of the lens and an optical axis of the image sensor are aligned, and are secondarily coupled to each other in the primarily coupled state.

A lens module includes a diffractive optical element, a lens, and a plurality of positioning elements, the diffractive optical element and the lens are matched and positively held together. First positioning grooves are defined in the diffractive optical element, and corresponding second positioning grooves are defined in the lens which is stacked on the diffractive optical element. Each positioning element is fixed in and entirely within a first positioning groove and a second positioning groove to fix and hold the diffractive optical element and the lens together.

A protective connector having a good connection reliability includes a main body, a plurality of conductive circuits embedded in the main body, two first conductive blocks formed on the main body, and two second conductive blocks formed on the main body and opposite to the two first conductive blocks. The two first conductive blocks and the two second conductive blocks are electrically connected to one of the plurality of conductive circuits, respectively. The disclosure further relates to a lens module.