Abstract: A method is for making a photonic chip including EO devices having multiple thicknesses. The method may include forming a first semiconductor layer over a semiconductor film, forming a second semiconductor layer over the first semiconductor layer, and forming a mask layer over the second semiconductor layer. The method may include performing a first selective etching of the mask layer to provide initial alignment trenches, performing a second etching, aligned with some of the initial alignment trenches and using the first semiconductor layer as an etch stop, to provide multi-level trenches, and filling the multi-level trenches to make the EO devices having multiple thicknesses.
Type:
Grant
Filed:
December 30, 2015
Date of Patent:
November 27, 2018
Assignees:
STMICROELECTRONICS SA, STMICROELECTRONICS (CROLLES 2) SAS
Inventors:
Charles Baudot, Alain Chantre, Sébastien Cremer
Abstract: We provide methods and apparatus for preparing crystalline-clad and crystalline core optical fibers with minimal or no breakage by minimizing the influence of thermal stress during a liquid phase epitaxy (LPE) process as well as the fiber with precisely controlled number of modes propagated in the crystalline cladding and crystalline core fiber via precisely controlling the diameter of crystalline fiber core with under-saturated LPE flux. The resulting crystalline cladding and crystalline core optical fibers are also reported.
Type:
Grant
Filed:
October 24, 2017
Date of Patent:
August 21, 2018
Assignees:
The Penn State Research Foundation, General Opto Solutions, LLC
Abstract: A method comprising: providing a core comprising a layer of electro-optic dielectric material, a first layer of semiconductor material provided below the electro-optic material and a second layer of the semiconductor material provided above the electro-optic material, and electrodes, configured for applying voltages.
Type:
Grant
Filed:
August 10, 2016
Date of Patent:
July 11, 2017
Assignee:
International Business Machines Corporation
Abstract: An apparatus and method for tuning optical components are provided. The apparatus and method may be used for wavelength selection in the context of optical communication. An example apparatus may include a plurality of tunable components, each having an optical output. The apparatus may also include a switch that during each period of a plurality of periods has a switch output that contains a selected one of the optical outputs. The apparatus may operate such that during each period of the plurality of periods, at least one of the tunable components other than the tunable component having the selected optical output is available for tuning.
Abstract: Exemplary embodiments of an article of manufacture and method according to the present disclosure are provided. For example, a first multi-clad fiber arrangement can be provided that comprises a first core and at least one first cladding which is structured to propagate at least one first electro-magnetic radiation therethrough. A second multi-clad fiber arrangement can also be provided that comprises a second core and at least one second cladding which is structured to propagate at least one second electro-magnetic radiation therethrough. Further, at least one portion can be provided in which the first and second claddings are fused to one another.
Abstract: A planar optical waveguide including a clad layer, an optical waveguide having a core embedded in the clad layer; and a groove formed in the clad layer and having a reflection interface for totally reflecting a leaked light leaked from the optical waveguide to the clad layer. Since the reflection interface for totally reflecting the leaked light is formed in the clad layer, the leaked light is prevented from entering into the tap coupler, and the variation of the branching ratio can be reduced.