An angle adjustment mechanism includes a hollow cylindrical fine adjustment seat (1), a hollow cavity of the fine adjustment seat (1) are provided with a tapered fine adjustment screw (3) and a mounting seat (2) having a tapered surface (201), the tapered fine adjustment screw (3) and the mounting seat (2) are opposed to each other along the axial direction, the tapered surface (201) of the mounting seat (2) is provided with four strip-shaped planes (202) evenly spaced in the circumferential direction, two adjacent strip-shaped planes (202) are overlapped with the tapered surfaces of two tapered fine adjustment screws (3) respectively, the tapered fine adjustment screw (3) can move forward or backward in a cavity formed by an inner wall of the fine adjustment seat (1) and the tapered surface (201) of the mounting seat (2) along a strip-shaped plane (202) that coincides with the tapered fine adjustment screw (3).

An augmented reality projection device is provided. The augmented reality projection device includes an excitation light source that generates excitation light and a fluorescent light detector that detects fluorescent light generated in the fluorescent light generation area and generates a fluorescent image. The device also includes a projector that converts an image signal for displaying a visual indicator in the fluorescent light generation area into visual indicator light. The device further includes a processor that controls operations of the excitation light source, the fluorescent light detector, and the projection. The device further includes a coaxial optics that delivers the excitation light and the visual indicator light to the fluorescent light generation area and delivers the fluorescent light to the fluorescent light detector.

Disclosed herein is a housing for containing a laser and lens for use in a laser light projection display, and a lighting device incorporating the laser within the housing and other light sources, such as light-emitting diodes (LEDs). The laser and lens are secured within a housing and maintain a spaced distance using a spacer. The lighting device uses the laser in combination with LEDs arrayed around the laser to provide a dual source light.

Techniques for reducing the risk for an unsafe eye condition associated with light sources. In an example, a light source package is described. The light source package includes a package body defining an interior volume and including an opening. The package also includes a light source contained inside the interior volume of the package body. The package also includes an optical element that occupies at least a portion of the opening of the package body. An electrically conductive material is disposed over a surface of the optical element. This material may be electrically coupled with a system. The system accesses an electrical parameter of the material, determines a damage associated with the optical element based on the electrical parameter, and initiates a corrective action associated with the light source based on the damage.

Techniques for reducing the risk for an unsafe eye condition associated with light sources. In an example, a light source package is described. The light source package includes a package body defining an interior volume and including an opening. The package also includes a light source contained inside the interior volume of the package body. The package also includes an optical element that occupies at least a portion of the opening of the package body. An electrically conductive material is disposed over a surface of the optical element. This material may be electrically coupled with a system. The system accesses an electrical parameter of the material, determines a damage associated with the optical element based on the electrical parameter, and initiates a corrective action associated with the light source based on the damage.

A motion generator including a frame, a mount movable with respect to the frame, and an emitting device having a beam outlet configured to emit an electromagnetic beam therefrom, and where the emitting device is coupled to and movable together with the mount relative to the frame. The motion generator is also operable in a first mode in which the beam outlet travels in a spiral pattern that alternatingly increases and decreases in radius, where for any given point in the spiral pattern the beam outlet produces a beam speed, a beam direction, an instantaneous beam radius, and a beam radius rate of change, and where the beam speed, the beam direction, and the beam radius rate of change may be adjusted independently.

A motion generator including a frame, a mount movable with respect to the frame, and an emitting device having a beam outlet configured to emit an electromagnetic beam therefrom, and where the emitting device is coupled to and movable together with the mount relative to the frame. The motion generator is also operable in a first mode in which the beam outlet travels in a spiral pattern that alternatingly increases and decreases in radius, where for any given point in the spiral pattern the beam outlet produces a beam speed, a beam direction, an instantaneous beam radius, and a beam radius rate of change, and where the beam speed, the beam direction, and the beam radius rate of change may be adjusted independently.

A phosphorescent sight system is provided comprising a rear sight for disposition along a proximal portion of a slide substrate of a firearm and a front sight for disposition along a distal portion of the slide substrate. The sight system may further comprise an optical waveguide disposed within a waveguide cavity of the rear sight or the front sight. Further, a phosphorescent element may be disposed adjacent a proximal portion of the optical waveguide.

A phosphorescent sight system is provided comprising a rear sight for disposition along a proximal portion of a slide substrate of a firearm and a front sight for disposition along a distal portion of the slide substrate. The sight system may further comprise an optical waveguide disposed within a waveguide cavity of the rear sight or the front sight. Further, a phosphorescent element may be disposed adjacent a proximal portion of the optical waveguide.

A laser illumination device includes a light source component, a micro-element lens, and a meniscus lens. The light source component emits a laser beam. The micro-element lens spreads out the laser beam. The meniscus lens has an incident face on which the laser beam from the micro-element lens is incident, and a light emission face that is provided on the opposite side from the incident surface and includes a convex shape, and the meniscus lens has a negative power for spreading out the incident laser beam from the micro-element lens.