A low numerical aperture fiber output diode laser module, which having several independent diode lasers, and collimated and converged the light beam, for the coupling the light to the core optical fiber with a core diameter of 105 um and a numerical aperture of 0.12. Compared with general products with a numerical aperture of 0.22, the light output angle is reduced to 55%, and use a general blue laser diode for verification. Use an optical software for facilitating the design and optimization of the parameters of the optical lens module.

The laser module includes a QCL element, a diffraction grating unit, a first lens holder, a second lens holder, and a mount member. The fourth mounting portion of the mount member is provided with a placement hole into which the protruding portion of the diffraction grating unit is inserted. The placement hole is longer than the protruding portion so that the protruding portion can be slid in the X-axis direction relative to the placement hole. A wall surface for positioning the diffraction grating unit is provided between the third mounting portion and the fourth mounting portion. The diffraction grating unit includes a positioning surface facing the wall surface. The diffraction grating unit is fixed to the fourth mounting portion in a state where the protruding portion is inserted into the placement hole and the positioning surface is in surface contact with the wall surface.

The laser module includes a QCL element, a diffraction grating unit, a first lens holder, a second lens holder, and a mount member. The first mounting portion has a first top surface on which the first lens holder is mounted via an adhesive layer. The third mounting portion has a third top surface on which the second lens holder is mounted via an adhesive layer. The second mounting portion has a second top surface located higher than the first top surface and the third top surface, a first side surface connecting the second top surface and the first top surface, and a second side surface connecting the second top surface and the third top surface. A notch extending from the second top surface to the first top surface or the third top surface is formed in at least one of the first side surface and the second side surface.

An optoelectronic component is provided that includes a radiation-emitting semiconductor chip, which emits electromagnetic radiation from a radiation exit surface during operation, a carrier comprising at least two first contact points, and a cover including at least two second contact points, wherein the at least two first contact points and the at least two second contact points are electrically conductively and/or thermally conductively connected to one another by a first plurality of nanowires and a second plurality of nanowires, and the nanowires provide a mechanically stable connection between the carrier and the cover. In addition, a method for producing an optoelectronic component is provided.

An optoelectronic component is provided that includes a radiation-emitting semiconductor chip, which emits electromagnetic radiation from a radiation exit surface during operation, a carrier comprising at least two first contact points, and a cover including at least two second contact points, wherein the at least two first contact points and the at least two second contact points are electrically conductively and/or thermally conductively connected to one another by a first plurality of nanowires and a second plurality of nanowires, and the nanowires provide a mechanically stable connection between the carrier and the cover. In addition, a method for producing an optoelectronic component is provided.

A mirror driving mechanism includes a plate-shaped base portion, a mirror that is installed at the base portion, and a temperature detecting section that is installed at the base portion and that detects a temperature of the base portion. The base portion includes a thin portion that is disposed away from an outer edge of the base portion and that has a through hole extending through the base portion in a plate-thickness direction of the base portion, a thick portion that is connected to the thin portion, that is thicker than the thin portion in the plate-thickness direction of the base portion, and that extends along the outer edge so as to surround the thin portion, and a first shaft portion extends into the through hole from an outer periphery of the through hole.

A light-emitting device includes first and second light-emitting elements, upper submounts, and a lower submount. The upper submounts include a first submount having a first upper surface and a first lateral surface located on a same side as an emission end surface of the first light-emitting element, and a second submount having a second upper surface and a second lateral surface located on a same side as an emission end surface of the second light-emitting element. In a top plan view, the first lateral surface is located forward relative to the second lateral surface, and the emission end surface of the first light-emitting element is located forward relative to the emission end surface of the second light-emitting element. At least a portion of the first lateral surface is protruded forward relative to an edge along which an upper surface and a lateral surface of the lower submount meet.

A light source device includes: a plurality of laser diodes that includes a first laser diode for emitting laser light of red color, a second laser diode for emitting laser light of green color, and a third laser diode for emitting laser light of blue color; a substrate directly or indirectly supporting the plurality of laser diodes; and a cap secured to the substrate and covering the plurality of laser diodes. The cap includes: a first glass portion configured to transmit the laser light that is emitted from the plurality of laser diodes, and a second glass portion. At least one of the first glass portion and the second glass portion comprises an alkaline glass region. The first glass portion and the second glass portion are bonded together via an electrically conductive layer that is in contact with the alkaline glass region. The first glass portion is bonded to the substrate.

A light source device includes: a plurality of laser diodes that includes a first laser diode for emitting laser light of red color, a second laser diode for emitting laser light of green color, and a third laser diode for emitting laser light of blue color; a substrate directly or indirectly supporting the plurality of laser diodes; and a cap secured to the substrate and covering the plurality of laser diodes. The cap includes: a first glass portion configured to transmit the laser light that is emitted from the plurality of laser diodes, and a second glass portion. At least one of the first glass portion and the second glass portion comprises an alkaline glass region. The first glass portion and the second glass portion are bonded together via an electrically conductive layer that is in contact with the alkaline glass region. The first glass portion is bonded to the substrate.

A pluggable optical connector is configured to be insertable into and removable from an optical communication apparatus, and to be capable of communicating a modulation signal and a data signal with the optical communication apparatus. A wavelength-tunable light source is configured to output an output light and a local oscillation light. An optical transmission unit is configured to output an optical signal generated by modulating the output light in response to the modulation signal. An optical reception unit is configured to demodulate an optical signal received by using the local oscillation light to the data signal. Pluggable optical receptors are configured in such a manner that an optical fiber is insertable into and removable from the pluggable optical receptors, and configured to be capable of outputting the optical signal to the optical fiber and transferring the optical signal received thorough the optical fiber to the optical reception unit.