An output coupler can be used to couple multiple channels of light from a semiconductor waveguide to an optical fiber for wavelength division multiplexing. To couple light of a wide bandwidth (e.g., equal to or greater than 100 nm), two symmetrical gratings on two sides of a Fabry Perot cavity is used. The two symmetrical gratings are optimized to both reflect light for a Fabry Perot resonator and couple light out of the semiconductor waveguide.

In accordance with an embodiment, a bandpass transmission filter having a center wavelength of transmission includes: a waveguide structure comprising a grating structure having changing grating pitch values configured to diffract radiation in the waveguide structure having a first wavelength lower than the center wavelength of transmission, and configured to reflect radiation in the waveguide structure having a second wavelength higher than the center wavelength of transmission; and a radiation absorbing structure configured to absorb radiation guided by the waveguide structure having a third wavelength higher than the second wavelength, wherein the radiation absorbing structure is an integrated part of the waveguide structure or comprises a layer arranged adjacent to the waveguide structure.

The invention relates to a waveguide and a polarisation splitter based on said waveguide, in which a rotation of an angle greater than zero is applied to a plurality of sections of a core material and a plurality of sections of a covering material, thereby achieving an independent control of the refractive indices of a zero-order transverse electric mode and a zero-order transverse magnetic mode. This document also describes a manufacturing method of said waveguide which allows the birefringence of the light that passes through the waveguide.

Systems and embodiments for an integrated photonics mode splitter and converter are provided herein. In certain embodiments, a system includes a substrate having a first index of refraction. Additionally, the system includes a waveguide layer on the substrate, wherein the waveguide has a second index of refraction different from the first index of refraction. Also, the waveguide layer includes one or more mode splitters that receive at least one of a first photon in a first mode and a second photon in a second mode through an input port and provide one of the first photon through a first output port and the second photon through a second output port. The waveguide layer also includes a mode converter coupled to the second output of a mode splitter, wherein the mode converter receives the second photon through a port and outputs the second photon in the first mode through the port.

A method for forming a device structure is disclosed. The method of forming a device structure includes forming a variable-depth structure in a device material layer using a laser ablation. A plurality of device structures is formed in the variable-depth structure to define slanted device structures therein. The variable-depth structure and the slanted device structures are formed using an etch process.

The present disclosure relates to semiconductor structures and, more particularly, to grating couplers integrated with one or more airgap and methods of manufacture. The structure includes: a substrate material comprising one or more airgaps; and a grating coupler disposed over the substrate material and the one or more airgaps.

The present disclosure relates to semiconductor structures and, more particularly, to grating couplers integrated with one or more airgap and methods of manufacture. The structure includes: a substrate material comprising one or more airgaps; and a grating coupler disposed over the substrate material and the one or more airgaps.

Apparatuses, systems and methods for optical coupling, optical integration, electro-optical coupling, and electro-optical packaging are described herein. Optical couplers may comprise various optical elements (e.g., mirrors as described herein) to relax optical assembly requirements and improve producibility. Optical couplers may improve fiber-to-chip, fiber-to-fiber and chip-to-chip optical connection. Optical couplers and optical components may be used to improve integration of, connection of, and/or packaging of optical systems and/or components with electrical systems and/or components.

An optical antenna, an optical phased array transmitter, and a lidar system using the same are provided. The optical antenna includes a substrate that forms at least a portion of a reflector layer having a first material, a waveguide layer disposed above the reflector layer and having a second material, a separation layer disposed between the waveguide layer and the reflector layer and having a third material. The waveguide layer further has a first grating array. The reflector layer reflects the light emitted downwards from the waveguide layer. The refractive index of the third material is smaller than that of either the first material or the second material.

An optical antenna, an optical phased array transmitter, and a lidar system using the same are provided. The optical antenna includes a substrate that forms at least a portion of a reflector layer having a first material, a waveguide layer disposed above the reflector layer and having a second material, a separation layer disposed between the waveguide layer and the reflector layer and having a third material. The waveguide layer further has a first grating array. The reflector layer reflects the light emitted downwards from the waveguide layer. The refractive index of the third material is smaller than that of either the first material or the second material.