The present technology can be used to control the current injection profile in the longitudinal direction of a high-power diode laser in order to optimize current densities as a function of position in the cavity to promote higher reliable output power and increase the electrical to optical conversion efficiency of the device beyond the level which can be achieved without application of this technique. This approach can be utilized, e.g., in the fabrication of semiconductor laser chips to improve the output power and wall plug efficiency for applications requiring improved performance operation.

According to various embodiments, there is provided an optical device including a first waveguide configured to guide a light wave along a longitudinal axis; a first grating at least partially formed in the first waveguide, the first grating arranged away from the longitudinal axis in a first direction; and a second grating at least partially formed in the first waveguide, the second grating arranged away from the longitudinal axis in a second direction; wherein the second direction is different from the first direction.

The present invention discloses a semiconductor laser comprising an optical waveguide structure which may include a lower waveguide layer, an active layer of multiple quantum wells and an upper waveguide layer, which are successively stacked from bottom to top, a grating layer being formed on upper portion of the active layer, wherein the upper waveguide layer, a cladding layer and a contact layer are formed as a ridge which has a light incidence end surface and a light output end surface, wherein a beam expanding structure is formed on one end of the output end surface. The beam expanding structure has a beam expanding portion with a shape gradually contracted inwards from the light output end surface. Preferably, the beam expanding portion has a horizontal divergence angle of 5° to 20°.

An optical coherence analysis system uses a laser swept source that is constrained to operate in a stable mode locked condition by modulating a drive current to the semiconductor optical amplifier as function of wavelength or synchronously with the drive voltage of the laser's tunable element based on stability map for the laser.

An optical device includes a semiconductor laser light source, a grating element and an optical transmission element. The grating element includes a ridge-type optical waveguide having an incident surface to which a semiconductor laser light is incident and an emitting surface from which an outgoing light having a desired wavelength is emitted, and a Bragg grating formed in the ridge-type optical waveguide. The light transmission element includes an optical transmission part having an incident surface to which the outgoing light from the ridge-type optical waveguide is incident. A near-field diameter in a horizontal direction at the incident surface of the optical transmission part is greater than a near-field diameter in the horizontal direction at the emitting surface of said ridge-type optical waveguide.

An edge-emitting semiconductor laser diode chip 15 with mutually opposed front and back end facet mirrors 22, 24. First and second ridges 26.sub.1, 26.sub.2 extend between the chip end facets 22, 24 to define first and second waveguides in an active region layer. Low and high slope efficiency laser diodes are thus formed that are independently drivable by respective electrode pairs 21.sub.1, 23.sub.1 and 21.sub.2, 23.sub.2. The single chip 15 thus incorporates two laser diodes sharing a common heterostructure, one with low slope efficiency optimized for low power operation with good power stability against temperature variations and random threshold current fluctuations in the close-to-threshold power regime, and the other with high slope efficiency optimized for high wall plug efficiency operation at higher output powers when the chip is operating far above threshold.

A smart light source configured for visible light communication. The light source includes a controller comprising a modem configured to receive a data signal and generate a driving current and a modulation signal based on the data signal. Additionally, the light source includes a light emitter configured as a pump-light device to receive the driving current for producing a directional electromagnetic radiation with a first peak wavelength in the ultra-violet or blue wavelength regime modulated to carry the data signal using the modulation signal. Further, the light source includes a pathway configured to direct the directional electromagnetic radiation and a wavelength converter optically coupled to the pathway to receive the directional electromagnetic radiation and to output a white-color spectrum. Furthermore, the light source includes a beam shaper configured to direct the white-color spectrum for illuminating a target of interest and transmitting the data signal.

Provided is an optical semiconductor element including: a stacked structure body 20 formed of a first compound semiconductor layer 21, a third compound semiconductor layer (active layer) 23, and a second compound semiconductor layer 22. A fundamental mode waveguide region 40 with a waveguide width W.sub.1, a free propagation region 50 with a width larger than W.sub.1, and a light emitting region 60 having a tapered shape (flared shape) with a width increasing toward a light emitting end surface 25 are arranged in sequence.

A method for manufacturing semiconductor devices includes: forming a plurality of semiconductor devices in a first region of a primary surface of a wafer; forming a plurality of cleave initiation portions in a second region of a primary surface different from the first region; and cleaving the wafer sequentially, using the plurality of cleave initiation portions as initiation points, starting from a cleave initiation portion that is relatively difficult to cleave among the plurality of cleave initiation portions. Forming the plurality of cleave initiation portions includes forming the plurality of first grooves by etching portions of the second region. Due to this, the yield and the manufacturing efficiency for semiconductor devices can be enhanced.

An optoelectronic semiconductor component comprises a first resonator mirror, an active region suitable for generating radiation, and a second resonator mirror, which are arranged one above another in each case along a first direction. The optoelectronic semiconductor component furthermore comprises a refractive index modulation layer within an optical resonator between the first resonator mirror and the second resonator mirror. The refractive index modulation layer comprises first regions of a first material having a first refractive index and also second regions of a second material having a second refractive index, wherein the first regions are arranged directly adjacent to the second regions in a plane perpendicular to the first direction.