A light source device includes: light-emitting portions arranged at least along an arrangement direction; one or more optical members including a first reflective surface and a second reflective surface, and configured to reflect light emitted from the plurality of light-emitting portions and emit the light in a predetermined direction; and a condenser lens configured to condense the light emitted from the one or more optical members. The first reflective surface is configured to reflect the light emitted from the plurality of light-emitting portions toward the second reflective surface. The second reflective surface is configured to reflect the light reflected by the first reflective surface. Each of the first reflective surface and the second reflective surface is a surface having a curvature in the arrangement direction. The curvature of the second reflective surface in the arrangement direction is greater than the curvature of the first reflective surface in the arrangement direction.

A light source device according to the present disclosure includes a light emitting element having a light emitting surface configured to emit first light having a first wavelength band, a wavelength conversion member which includes a phosphor, and which is configured to convert the first light emitted from the light emitting element into second light having a second wavelength band different from the first wavelength band, and a reflecting member having a reflecting surface configured to reflect the second light generated by the wavelength conversion member. The wavelength conversion member has a first face which crosses a longitudinal direction of the wavelength conversion member, and which emits the second light, a second face which crosses the longitudinal direction of the wavelength conversion member, and which is located at an opposite side to the first face, and a third face crossing the first face and the second face. The light emitting surface is disposed so as to be opposed to at least a part of the third face. The reflecting surface is disposed so as to be opposed to the second face. At least one of the second face and the reflecting surface is a rough surface.

A light-emitting device includes: a substrate comprising a base; a semiconductor laser element disposed on an upper surface of the base; a sealing member located above the base and fixed to the substrate, wherein the sealing member and the substrate define a sealed space in which the semiconductor laser element is located; and a lens member fixed to the sealing member by adhesive, the lens member comprising a lens section through which light emitted from the semiconductor laser element passes. A space between the sealing member and the lens member is open to an area outside the light-emitting device.

Embodiments of the present disclosure provide a laser array, a laser source, and a laser projection device, and relate to the field of laser display technologies. The laser array includes a light emitting portion for emitting a laser light beam; a light transmitting portion disposed along a light emitting direction of the light emitting portion for transmitting the laser light beam; where the light transmitting portion includes a first light transmitting region and a second light transmitting region, the first light transmitting region and the second light transmitting region are disposed such that light beams transmitting through the two regions have different polarization directions, which can reduce coherence of the laser light beam emitted from the laser array, thereby facilitating elimination of a speckle.

A laser device for dentistry has a body, a light source group, and a light guiding pipe. The body has an outer casing, an operating module, and a controlling module. The light source group is disposed in the body and has multiple light-emitting elements, a reflector, a collimating mirror, and a focusing mirror. Each light-emitting element is a laser diode, is disposed at a connecting portion of the body and is electrically connected to the controlling module. The reflector is mounted around the light-emitting elements. The collimating mirror is disposed on a side of the reflector away from the light-emitting elements. The focusing mirror is disposed on a side of the collimating mirror away from the reflector. The light guiding pipe is detachably connected to the connecting portion of the body and is located on a front side of the light source group.

Apparatus for generating a line-beam includes a diode-laser bar, a linear micro-lens array, and a plurality of lenses spaced apart and arranged along an optical axis. The linear micro-lens array and the lenses shape laser-radiation emitted by the diode-laser bar to form a uniform line-beam in an illumination plane. The lenses project a far-field image of the diode-laser bar onto an image plane proximate to the illumination plane. The diode-laser bar is rotated from parallel alignment with the linear micro-lens array for providing uniform line-beam illumination over a range of locations along the optical axis.

Provide is a lens which outputs light, emitted by a plurality of light sources, with uniform light distribution. The lens includes a lens body having a first surface which is flat and has an incident hole formed therein, and a second surface which is convex and opposite the first surface; and a plurality of incident surfaces which are recessed from the incident hole toward the second surface, each of the plurality of incident surfaces corresponding to a light source of the plurality of light.

A linear light concentrator includes a light emitting body and first and second optical element groups, wherein the first optical element group is divided in first and second directions into first optical elements, each having characteristics to deflect a beam in the first direction, and the characteristics of the first optical elements adjacent in the second direction are different, the second optical element group is divided in at least the first direction into second optical elements having a power in the second direction, and center axes of refraction of adjacent second optical elements are shifted in the second direction, the characteristics deflect a beam from each unit of the first optical elements arranged in the first direction toward one of apertures of the second optical element group, and a length in the second direction of the second optical element is longer than that of the first optical element.

A laser navigational system for a vehicle having a lighting assembly configured for emission of light. A lens array assembly receives incoming light from the lighting assembly and changes the direction of the incoming light received from the lighting assembly such that the outgoing light emanating from the lens array assembly is collimated in a first direction but diverges along a different, second direction. A scanning unit aligns with the lighting assembly to direct the collimated beam in two orthogonal directions. The lighting assembly, the lens array assembly and the scanning unit are configured to direct the light to form a visual beacon that guides navigation of the vehicle to a location.

A semiconductor laser module comprises a tapered laser diode and/or a tapered amplifier diode equipped with beam shaping optics. The tapered laser diode and/or the tapered amplifier diode includes an emission facet for emitting a laser beam along a beam axis. The beam-shaping optics comprise a plano-convex cylindrical lens oriented so as to change divergence of the beam in the fast axis direction, the plano-convex spherical cylindrical lens having a planar surface arranged facing the facet and a circular cylindrical surface facing away from the facet. The refractive index of lens may be uniform throughout the entire lens. Alternatively, the lens may have a refractive index varying in the direction of the slow axis and/or in the direction of the fast axis.