In one embodiment the semiconductor laser comprises a carrier and an edge-emitting laser diode which is mounted on the carrier and which comprises an active zone for generating a laser radiation and a facet with a radiation exit region. The semiconductor laser further comprises a protective cover, preferably a lens for collimation of the laser radiation. The protective cover is fastened to the facet and to a side surface of the carrier by means of an adhesive. A mean distance between a light entrance side of the protective cover and the facet is at most 60 μm. The semiconductor laser is configured to be operated in a normal atmosphere without additional gas-tight encapsulation.

In one embodiment the semiconductor laser comprises a carrier and an edge-emitting laser diode which is mounted on the carrier and which comprises an active zone for generating a laser radiation and a facet with a radiation exit region. The semiconductor laser further comprises a protective cover, preferably a lens for collimation of the laser radiation. The protective cover is fastened to the facet and to a side surface of the carrier by means of an adhesive. A mean distance between a light entrance side of the protective cover and the facet is at most 60 μm. The semiconductor laser is configured to be operated in a normal atmosphere without additional gas-tight encapsulation.

A micromechanical optical component having a substrate, a spacer, and a cover, which are positioned one above the other and delimit a hermetically sealed cavity. A semiconductor laser is situated in the cavity, on the substrate. An optical element, which is attached to the spacer, is positioned in a beam path of the semiconductor laser. A method for manufacturing a micromechanical optical component is also described.

A micromechanical optical component having a substrate, a spacer, and a cover, which are positioned one above the other and delimit a hermetically sealed cavity. A semiconductor laser is situated in the cavity, on the substrate. An optical element, which is attached to the spacer, is positioned in a beam path of the semiconductor laser. A method for manufacturing a micromechanical optical component is also described.

There are provided a light emitting device capable of forming a light emitting element on a suitable substrate and a method of manufacturing the same.

A light emitting device according to the present disclosure includes: a first substrate; a plurality of light emitting elements that are provided on a first surface of the first substrate; and a second substrate that is provided on a second surface of the first substrate opposite to the first surface.

There are provided a light emitting device capable of forming a light emitting element on a suitable substrate and a method of manufacturing the same.

A light emitting device according to the present disclosure includes: a first substrate; a plurality of light emitting elements that are provided on a first surface of the first substrate; and a second substrate that is provided on a second surface of the first substrate opposite to the first surface.

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.

Described herein are photonic sources and related system architectures that can satisfy the optical power requirements of large photonic accelerators. Some embodiments relate to a computer comprising a photonic accelerator configured to perform matrix multiplication; a fiber array optically coupled to the photonic accelerator; and a photonic source optically coupled to the fiber array. The photonic source comprising a laser array comprising a plurality of monolithically co-integrated lasers, and a coupling lens array comprising a plurality of monolithically co-integrated lenses, the coupling lens array optically coupling the laser array to the fiber array. The laser array is configured to output between 0.1 W and 10 W of optical power.

Described herein are photonic sources and related system architectures that can satisfy the optical power requirements of large photonic accelerators. Some embodiments relate to a computer comprising a photonic accelerator configured to perform matrix multiplication; a fiber array optically coupled to the photonic accelerator; and a photonic source optically coupled to the fiber array. The photonic source comprising a laser array comprising a plurality of monolithically co-integrated lasers, and a coupling lens array comprising a plurality of monolithically co-integrated lenses, the coupling lens array optically coupling the laser array to the fiber array. The laser array is configured to output between 0.1 W and 10 W of optical power.

A polarization control member includes a first dichroic mirror having a first incident face, a second dichroic mirror joined to the first dichroic mirror, the second dichroic mirror having a second incident face, and a waveplate joined to the first incident face of the first dichroic mirror.