A method of forming an emitting array of waveguides, comprising providing a plurality of waveguides that exhibit different propagation constants so as to ensure that nearby waveguides do not couple evenly over parallel propagation lengths by varying a length in one or more dimensions of respective waveguides, whereby the respective waveguides are phase mismatched with at least their nearest neighbor.

A reconfigurable integrated optical microswitch device (1) comprises a base layer (100), an adhesive layer (102) made of non-conducting material, a first layer of driving electrodes (104) arranged above the non-conducting adhesive layer (102), a layer of electro-optical material (106) arranged on the first layer of driving electrodes (104), a plurality of waveguides (50) afforded in the layer of electro-optical material (106), and a second layer of driving electrodes (110), arranged above the layer of electro-optical material (106) and connected to the plurality of waveguides (50). The device further comprises a layer of dielectric insulating material (108) arranged between the layer of electro-optical material (106) and the second layer of driving electrodes (110).

A calibration system and related methods for optical phased array chips. The calibration system includes an adjustable mount module, an infrared microscopic observation module, an arrayed driver module, a two-dimensional laser beam scanning module, a photoelectric conversion module and an upper computer, and utilizes computer-vision-enabled positioning and phase error compensation algorithms as software components. Collimated laser is emitted from the target beamforming angle and aimed at the emission aperture of the chip, and is subsequently sampled by the array elements in a reversed injection manner. Based on the reciprocity of light propagation, by maximizing the power reversely output from the bus waveguide of the optical phased array chip, beamforming at the target angle is achieved supported by software implementations of optimization algorithms. The system and related methods are readily achievable, highly automated, and offers fast and batch calibration with relatively low expenses, good flexibility and long-term compatibility.

It is an object of this invention to provide an optical waveguide, an optical concentration measuring device, and a method for manufacturing an optical waveguide capable of achieving an improvement of evanescent wave exuding efficiency of propagating light and light extraction efficiency. A core layer provided in an optical waveguide has a first portion having a first film thickness, a second portion having a second film thickness different from the first film thickness, and a third portion connecting the first portion and the second portion. The third portion is formed so that the film thickness is gradually increased from the second portion having the smaller film thickness toward the first portion having the larger film thickness between the first portion and the second portion, and the maximum inclination angle is 10° or more and 45° or less.

An optical waveguide apparatus including a first dispersion unit and a separation unit. The first dispersion unit is connected to the separation unit, the first dispersion unit is configured to disperse a frequency component of at least one first optical signal, and the separation unit is configured to separate, into at least one second optical signal based on configuration information, the frequency component that is of the at least one first optical signal and that is dispersed by the first dispersion unit. The separation unit is implemented by a variable optical waveguide, and the variable optical waveguide is an optical waveguide that implements at least one of the following functions based on the configuration information: forming an optical waveguide, eliminating an optical waveguide, and changing a shape of an optical waveguide.

Methods, apparatus, devices, and systems for displaying three-dimensional objects by individually diffracting different colors of light are provided. In one aspect, a system includes a display having a plurality of display elements and an optical device configured to diffract a plurality of different colors of light to the display. The optical device is configured such that, when the plurality of different colors of light is incident on the optical device, the optical device separates light of individual colors of the different colors while suppressing crosstalk between the different colors.

An optical device includes a plurality of optical waveguide units arranged in a first direction. Each of the optical waveguide units includes a first mirror having a first reflecting surface, a second mirror having a second reflecting surface facing the first reflecting surface, and at least one optical waveguide region located between the first mirror and the second mirror. The distance between the first reflecting surface and the second reflecting surface is different for each of the optical waveguide units.

Provided is an optical phase array antenna including a coupling part configured to receive light from a laser generator, an optical distributor configured to distribute the light transmitted from the coupling part to a plurality of antenna element waveguides, a phase modulator configured to modulate a phase of the light transmitted through the plurality of antenna element waveguides, and a light outputter configured to output the light modulated by the phase modulator, the light outputter including the plurality of antenna element waveguides extending in one direction, wherein each of the plurality of antenna element waveguides includes a double grating antenna part in which a downward-curved portion curved downward from an upper surface and an upward-curved portion curved upward from a lower surface are repeatedly formed in the one direction.

An optical phased array includes a first multitude of tiles forming an array of optical signal transmitters and/or receivers. Each such tile includes optical components for processing of an optical signal. The phased array further includes a second multitude of tiles each positioned below one of the first multitude of tiles. Each of the second multitude of tiles includes a circuit for processing of an electrical signal and is in electrical communication with one or more of the first multitude of tiles. Each of the first multitude of tiles is adapted to receive in a modular form, be adjacent to, and couple to at least one additional tile that is similar to that tile. Each of the second multitude of tiles is adapted to receive in a modular form, be adjacent to, and couple to at least one additional tile that is similar to that tile.

Provided in a method of fabricating an optical element array including providing a silicon substrate, providing a first element layer on the silicon substrate, the first element layer including a plurality of passive optical elements, providing a plurality of semiconductor blocks on a compound semiconductor wafer, providing semiconductor dies by dicing the compound semiconductor wafer by the plurality of semiconductor blocks, and providing a second element layer by providing the semiconductor dies on the first element layer, each of the plurality of semiconductor blocks contacting at least one corresponding passive optical element from among the plurality of passive optical elements.