A power over fiber system includes a power sourcing equipment, a powered device, an optical fiber cable and a converter. The power sourcing equipment includes a semiconductor laser that oscillates with electric power, thereby outputting feed light. The powered device includes a photoelectric conversion element that converts the feed light into electric power. The optical fiber cable has one end connectable to the power sourcing equipment and another end connectable to the powered device to transmit the feed light. The converter converts a wavelength of the feed light.

A semiconductor laser device includes a semiconductor laser element, a base material supporting the semiconductor laser element, and a wiring portion formed on the base material and constituting a conduction path to the semiconductor laser element. The base material includes a mounting face oriented to one side in a thickness direction of the base material and having the semiconductor laser element mounted thereon, while also including an emission part located on one side with respect to the semiconductor laser element in a first direction perpendicular to the thickness direction. Light from the semiconductor laser element is emitted through the emission part to the outside.

A semiconductor laser device includes a semiconductor laser element, a base material supporting the semiconductor laser element, and a wiring portion formed on the base material and constituting a conduction path to the semiconductor laser element. The base material includes a mounting face oriented to one side in a thickness direction of the base material and having the semiconductor laser element mounted thereon, while also including an emission part located on one side with respect to the semiconductor laser element in a first direction perpendicular to the thickness direction. Light from the semiconductor laser element is emitted through the emission part to the outside.

An electroabsorption modulated laser having a first face, a second face, an optical cavity and an active region, the optical cavity being defined by a semiconductor substrate and having a length extending between the first face and the second face, and the active region being configured for injection of charge into the cavity and having effective bandgap energies at respective distances along the length of the cavity, the electroabsorption modulated laser comprising a first modulator section extending between a first position and a second position and comprising a first part of the active region, and a second modulator section extending between the second position and a third position and comprising a second part of the active region, wherein the bandgap energy of the first part of the active region adjacent the first position is higher than the bandgap energy adjacent the second position.

Provided are a light source device that has a reduced height and in which the number of components is reduced, a method for manufacturing the light source device, and an electronic device. A light source device according to an embodiment includes: a substrate; a light generating element that is provided on a first surface of the substrate and emits generated light from a second surface opposite to the first surface via the substrate; and a lens that is provided at a position corresponding to the light generating element in the second surface of the substrate and increases an NA.

An optical unit for a laser processing system includes a laser diode including a plurality of laser emitters which emit laser light, a lens unit including a plurality of lenses, a holding block having a light-transmitting property, and a light-shielding film. The holding block and the laser diode are bonded to each other with a first adhesive, and the lens unit and the holding block are bonded to each other with a second adhesive. The light-shielding film is located between the lens unit and the holding block.

An optical unit for a laser processing system includes a laser diode including a plurality of laser emitters which emit laser light, a lens unit including a plurality of lenses, a holding block having a light-transmitting property, and a light-shielding film. The holding block and the laser diode are bonded to each other with a first adhesive, and the lens unit and the holding block are bonded to each other with a second adhesive. The light-shielding film is located between the lens unit and the holding block.

An optical module includes a light-forming unit to form light. The light-forming unit includes a base member having an electronic temperature control module, a base plate, a plurality of submounts, and a microelectromechanical system (MEMS) base. The light-forming unit also includes a plurality of laser diodes arranged on the submounts, a filter arranged on the base plate and located to receive the light emitted from the plurality of laser diodes and multiplex the emitted light, a MEMS arranged on the MEMS base and located to receive the light multiplexed by the filter. The MEMS includes a scanning mirror to scan the light multiplexed by the filter, and the electronic temperature control module regulates a temperature range of the MEMS. The light-forming unit also includes a protective member surrounding and sealing the light-forming unit, which includes a base body and a lid welded to the base body.

A circuit board (100) has a first surface (102). A semiconductor chip (200) (first semiconductor chip) is located at the first surface side (102) of the circuit board (100). An insulating layer (300) covers the first surface (102) of the circuit board (100) and the semiconductor chip (200). A conductive path (310) (first conductive path) is electrically connected to the semiconductor chip (200) and extends in the insulating layer (300). A waveguide (320) is optically coupled to the semiconductor chip (200) and extends in the insulating layer (300).

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.