Included are: a laser light source which emits a plurality of laser beams; an aspherical lens which the plurality of laser beams emitted from the laser light source enters and which converts the plurality of laser beams into convergent beams; and a phosphor which is irradiated with the convergent beams from the aspherical lens as excitation beams to generate fluorescence, wherein the plurality of laser beams have different spread angles in a horizontal direction and a vertical direction and enter the aspherical lens while arranged in a direction in which the spread angle is smaller, from among the horizontal direction and the vertical direction, and the aspherical lens has a function of equalizing a light intensity in a direction in which the spread angle is larger, from among the horizontal direction and the vertical direction.

In one embodiment, the semiconductor laser comprises a housing in which multiple laser diode chips are encapsulated. The housing comprises a cover panel and/or a lateral wall which is permeable to the generated laser radiation. The cover panel and/or the lateral wall has a light outlet surface with adjacent outlet regions. Each of the outlet regions is paired with precisely one of the laser diode chips. The light outlet surface is arranged downstream of a light outlet plane. The cover panel and/or the lateral wall has a different average thickness in the outlet regions such that the optical wavelength for the laser radiation of all of the laser diode chips is the same up to the light outlet plane with a tolerance of maximally 1.5 μm.

A light-emitting device, having a laser light device that is designed to emit a multiplicity of laser light beams. Ellipticities of beam cross-sections of the laser light beams differ at least partly from one another. The light-emitting device includes a beamforming device that is introduced into the beam path of at least one of the laser light beams and that is designed to adapt the ellipticities of the beam cross-sections of the laser light beams to one another, and a beam-combining device that is designed to combine the laser light beams to form an overall light beam, after the adapting of the ellipticities of the beam cross-sections by the beamforming device.

To provide a laser processing machine, a processing method, and a laser light source that are capable of miniaturization. The laser processing machine includes a laser light source and an optical system. The laser light source includes a light emitting body including a substrate and a bottom emission type vertical-cavity surface-emitting laser element that is provided on one surface of the substrate and emits an excitation light beam from another surface side of the substrate, and a cavity that is disposed in contact with the light emitting body on the other surface side of the substrate and oscillates a pulsed laser beam by incidence of the excitation light beam. The optical system causes the pulsed laser beam to contract and applies the pulsed laser beam to a workpiece.

A laser arrangement includes a laser array, and an optical arrangement. The laser array includes lasers in a first pattern emitting a same laser emission profile around a first optical axis with a divergence angle θ/2. The optical arrangement has a diffusor with an array of optical elements in a second pattern, with a second optical axis, and with an illumination pattern along a first illumination axis in a field-of-view if laser light is received within a defined range smaller than or equal to a range of angles between −/+θ with respect to the second optical axis. A row of lasers parallel to the first illumination axis has a pitch p. A row of m optical elements is parallel to the first axis. Each optical element has a diameter L, and contacts its neighbor. The n lasers and the m optical elements satisfy n*p=m*L with a deviation smaller than +/−5%.

In various embodiments, laser resonator modules produce output beams via manipulation of input beams on opposite sides of the module. The input beams are emitted by one or more beam emitters that may be cooled using a liquid coolant cavity. The liquid coolant cavity may be isolated from optical elements utilized to manipulate the input beams, at least in part, by an isolation wall protruding from the base plate of the resonator module.

Light from an array of laser light sources are spread to cover the modulating face of a DMD or other modulator. The spread may be performed, for example, by a varying curvature array of lenslets, each laser light directed at one of the lenslets. Light from neighboring and/or nearby light sources overlap at a modulator. The lasers are energized at different energy/brightness levels causing the light illuminating the modulator to itself be modulated (locally dimmed). The modulator then further modulates the locally dimmed lights to produce a desired image. A projector according to the invention may utilize, for example, a single modulator sequentially illuminated or separate primary color modulators simultaneously illuminated.

A structure can be provided for collimating light from a light source (e.g., vertical cavity surface emitting diodes). The structure can include at least one light source, a pit formed at an output of the at least one light source and a microbead formed in the pit. Microbeads can function as a lens to collimate light emitting from the at least one light source. The structure can provide by forming an array of VCSELs on a substrate, forming a pit in front of each VCSEL of the array of VCSELs, and assembling a microbead in each pit formed in front of each VCSEL. The microbeads can thereby function as lenses to collimate light emitted from the VCSELs.

A light source optical system used with an excitation light source configured to emit first color light includes a wavelength conversion unit configured to receive the first color light emitted by the excitation light source and emit second color light with a wavelength different from a wavelength of the first color light, There is a first optical system having a positive power and a second optical system having a positive power provided in this order in an optical path between the excitation light source and the wavelength conversion unit. When a ray parallel to an optical axis of the first optical system is incident on the first optical system, a ray emitted from the first optical system is incident on the second optical system while approaching the optical axis. The second optical system has under-corrected spherical aberration at a paraxial focal position of the second optical system.

A laser projecting device and a light-combining lens are provided. The light-combining lens is a one-piece structure, and has a difference of refractive indexes less than 0.2. The light-combining lens includes collimation surfaces, reflection surfaces, and a light emergent surface. Each collimation surface defines a collimation path inside the light-combining lens. The reflection surfaces respectively located at the collimation paths are parallel to each other and arranged along an arrangement direction. The light emergent surface is located at the arrangement direction. Each reflection surface and the corresponding collimation path have an acute angle therebetween to define a reflection path. The reflection paths are overlapped in the light-combining lens to define a light-combining path. The light combining path passes through at least one of the reflection surfaces that allows light to pass therethrough along the light-combining path, and passes through the light-combining lens from the light emergent surface.