The present embodiment relates to a light emitting device having a structure capable of removing zero order light from output light of an S-iPM laser. The light emitting device includes a semiconductor light emitting element and a light shielding member. The semiconductor light emitting element includes an active layer, a pair of cladding layers, and a phase modulation layer. The phase modulation layer has a basic layer and a plurality of modified refractive index regions, each of which is individually disposed at a specific position. The light shielding member has a function of passing through a specific optical image output along an inclined direction and shielding zero order light output along a normal direction of a light emitting surface.

A device including: a transfer substrate including electric connection elements; a plurality of first monolithic elementary chips bonded and electrically connected to the transfer substrate, each first elementary chip including at least one LED and one integrated electronic circuit for controlling said at least one LED, the device further including, associated with at least one of the first elementary chips, a second elementary chip including a vertical cavity surface-emitting laser diode, bonded and electrically connected to the transfer substrate, the first elementary chip including an integrated electronic circuit for controlling said laser diode.

The present embodiment relates to a semiconductor light emitting element having a structure that enables removal of zero-order light from output light of an S-iPM laser. The semiconductor light emitting element includes an active layer, a pair of cladding layers, and a phase modulation layer. The phase modulation layer has a base layer and a plurality of modified refractive index regions each of which is individually arranged at a specific position. One of the pair of cladding layers includes a distributed Bragg reflector layer which has a transmission characteristic with respect to a specific optical image outputted along an inclined direction with respect to a light emission surface and has a reflection characteristic with respect to the zero-order light outputted along a normal direction of the light emission surface.

An optoelectronic device employs a surface-trapped TM-polarized optical mode existing at a boundary between a distributed Bragg reflector (DBR) and a homogeneous medium, dielectric or air. The device contains a resonant optical cavity surrounded by two DBRs, and an additional DBR section on top supporting the surface-trapped mode. Selective chemical transformation, like selective oxidation, etching or alloy composition intermixing form a central core and a periphery having different vertical profiles of the refractive index. Therefore, the longitudinal VCSEL mode in the core is non-orthogonal to the surface-trapped mode in the periphery, and the two modes can be transformed into each other. Such transformation allows fabrication of a number of optoelectronic devices and systems like a single transverse mode VCSEL, an integrated optical circuit operating as an optical amplifier, an integrated optical circuit combining a VCSEL and a resonant cavity photodetector, etc.

A VCSEL may include a bottom DBR mirror and a top DBR mirror above the bottom DBR mirror. The VCSEL may include a vertical optical cavity located within a portion of the bottom and top DBR mirrors. The vertical optical cavity may be configured to emit an optical signal. The VCSEL may include a lateral feedback optical cavity located within a different portion of the bottom and the top DBR mirrors configured to receive a feedback bias signal configured to bias the lateral feedback optical cavity to adjust the optical signal. The VCSEL may include an active region formed between the bottom and the top DBR mirrors that may include an oxide layer defining an oxide aperture. The VCSEL may include an isolation implant configured to electrically isolate the vertical optical cavity from the feedback optical cavity and to create a first and a second aperture within the oxide aperture.

An optical modulating device may include a plurality of quantum dot (QD)-containing layers having QDs and a plurality of refractive index change layers. The QD-containing layers may be disposed between the refractive index change layers, respectively. The optical modulating device may be configured to modulate light-emission characteristics of the plurality of QD-containing layers. At least two of the QD-containing layers may have different central emission wavelengths. At least two of the plurality of refractive index change layers may include different materials or have different carrier densities.

An electro-optic modulator device includes a modulation region, a reflecting region, a conductive line and an anti-reflecting region. The modulation region includes a doped region. The reflecting region is over the modulation region. The conductive line is connected to the doped region. The conductive line extends through the reflecting region. The anti-reflecting region is on an opposite surface of the modulation region from the reflecting region.

A tunable laser device is provided. The tunable laser device includes an active layer configured to generate first light by a first source; first and second reflective layers spaced apart from each other having the active layer disposed between the first reflective layer and the second reflective layer to form a resonance cavity; and a variable refractive index unit in the resonance cavity and having a refractive index being variable according to a second source, the second source being different from the first source.

An optical device includes a plurality of radiation-emitting elements provided on a substrate, and a microlens arranged on the substrate such that a beam of radiation emitted by each of the plurality of radiation-emitting elements propagates through the microlens. Also disclosed is a method of manufacturing the optical device, and a time-of-flight sensor implementing the optical device.

An atomic oscillator includes a gas cell housing alkali metal atoms, a light source providing light to the gas cell, and a light detector that detects an amount of light transmitted through the gas cell. The light source includes a substrate, a first mirror layer on an upper portion of the substrate, an active layer on an upper portion of the first mirror layer, a second mirror layer on an upper portion of the active layer, a first contact layer on an upper portion of the second mirror layer, a light absorption layer on an upper portion of the first contact layer, and a second contact layer on an upper portion of the light absorption layer. As such, an output wavelength and the light output of the light source can be independently adjusted.