Abstract: Embodiments describe bi-directional AWGs comprising a first input waveguide coupled to a first free propagation region to input light into a dispersive waveguide array, a second input waveguide coupled to a second free propagation region to input light into the dispersive waveguide array, a first plurality of output waveguides coupled to the first free propagation region to output light from the dispersive waveguide array received from the second input waveguide, and a second plurality of output waveguides coupled to the second free propagation region to output light from the dispersive waveguide array received from the first input waveguide. At least one of these FPRs reduces potential crosstalk received at their respective output waveguides by having at least one of their input waveguides or plurality of output waveguides angled offset from a center of the dispersive waveguide array to attenuate carrier waves that can be present at the output waveguides.

Abstract: Embodiments describe optical devices including a first waveguide, comprising a first cross-sectional area, to receive a light comprising a first optical mode, and a second waveguide, adjacent to the first waveguide, to receive a light comprising a second optical mode orthogonal to the first optical mode. The second waveguide comprises a second cross-sectional area different than the first waveguide such that an absorption/gain coefficient of the second waveguide for light comprising the second optical mode is equal to an absorption/gain coefficient of the first waveguide for light comprising the first optical mode. The optical devices may comprise modulators, photodetectors, or semiconductor optical amplifiers (SOAs).

Abstract: Described herein are optical sensing devices for photonic integrated circuits (PICs). A PIC may comprise a plurality of waveguides formed in a silicon on insulator (SOI) substrate, and a plurality of heterogeneous lasers, each laser formed from a silicon material of the SOI substrate and to emit an output wavelength comprising an infrared wavelength. Each of these lasers may comprise a resonant cavity included in one of the plurality of waveguides, and a gain material comprising a non-silicon material and adiabatically coupled to the respective waveguide. A light directing element may direct outputs of the plurality of heterogeneous lasers from the PIC towards an object, and one or more detectors may detect light from the plurality of heterogeneous lasers reflected from or transmitted through the object.

Abstract: Embodiments of the invention describe heterogeneous photonic integrated circuits (PIC) wherein a first silicon region is separated from the heterogeneous semiconductor material by a first distance, and a second silicon region is separated from the heterogeneous semiconductor material by a second distance greater than the first distance. Thus embodiments of the invention may be described as, in heterogeneous regions of a heterogeneous PIC, silicon waveguides using multiple heights of the silicon waveguide, or other structures with multiple offset heights between silicon and heterogeneous materials (as described herein).

Abstract: Embodiments of the invention describe systems, apparatuses and methods for providing athermicity and a tunable spectral response for optical filters. Finite impulse response (FIR) filters are commonly implemented in photonic integrated circuits (PICs) to make devices such as wavelength division multiplexing (WDM) devices, asymmetric Mach-Zehnder interferometers (AMZIs) and array waveguide gratings (AWGs). Athermicity of an FIR filter describes maintaining a consistent frequency transmission spectrum as the ambient temperature changes. A tunable spectral response for an FIR filter describes changing the spectrum of an FIR filter based on its application, as well as potentially correcting for fabrication deviations from the design. In addition, embodiments of the invention reduce energy dissipation requirements and control complexity compared to prior art solutions.

Abstract: Embodiments of the invention describe photonic integrated circuits (PICs) for accomplishing polarization splitting and rotation. Embodiments of the invention include a first waveguide to receive light comprising orthogonally polarized transverse electric (TE) and transverse magnetic (TM) modes, and a second waveguide disposed below the first waveguide and comprising a reverse taper-shaped side to adiabatically receive one of the polarization modes (e.g., the TE mode) of the received light from the first waveguide. Said horizontal offset between the first and the reverse taper-shaped side of the second waveguide comprises an offset such that, for example, the TM mode of the received light is rotated to a TE mode in the first waveguide. The above described offsets and taper shaped structures may also be used in an optical combiner.

Abstract: Described herein are methods, systems, and apparatuses to utilize an electro-optic modulator including one or more heating elements. The modulator can utilize one or more heating elements to control an absorption or phase shift of the modulated optical signal. At least the active region of the modulator and the one or more heating elements of the modulator are included in a thermal isolation region comprising a low thermal conductivity to thermally isolate the active region and the one or more heating elements from a substrate of the PIC.

Abstract: Embodiments of the invention describe wavelength stabilization of selective optical components (e.g., multiplexers, de-multiplexers) using optical mode steering. An additional waveguide structure is coupled to the free propagation region of the selective optical component; this additional waveguide structure moves a spatial position or a direction of a propagation of an optical mode at the free propagation region in order to adjust a wavelength response of the component. By moving the position or direction of the optical mode, the wavelength response of the component may be changed; in other words, by tuning the position or direction of the optical mode, a component's wavelength/channel response is “remapped” to account for the mis-targeting (i.e., wavelength shift) related to a temperature change or a design/manufacturing defect.

Abstract: Embodiments of the invention describe a skew directional coupler for a plurality of waveguides. Said coupler includes a first waveguide on a first plane and a second waveguide on a second plane separate from the first plane. In embodiments of the invention, the first waveguide is disposed on top of the second waveguide to form an overlapping region of a segment of the first waveguide and a segment of the second waveguide, wherein an optical axis of the segment of the first waveguide is horizontally skew to an optical axis of the segment of the second waveguide, and wherein light is to be passively transmitted between the first and second waveguide segments via mode hybridization.

Abstract: Embodiments of the invention describe integrating a phase shifting component into a cavity of a laser. Said phase shifter is capable of a continuous phase shift at a single wavelength over a large range (where the maximum energy consumption of the phase shifting component does not scale with the phase shifting range). In other words, said phase shifter is used to form a configurable optical cavity length for a laser. Embodiments of the invention thus utilize a plurality of optical cavity lengths—including one or more optical cavity lengths to potentially shift the phase of the output optical signal, to maintain a laser cavity's output wavelength and avoid spatial mode-hops in the presence of fluctuations such as temperature drift or changes to the drive current of the laser.

Abstract: Embodiments of the invention enable polarization diversity using a more general component than current polarization splitter and rotator solutions. Devices such as an optical receiver, transmitter or duplexer may utilize polarization diversity to efficiently process incoming signals regardless of the signal's polarization. Embodiments of the invention may be described as enabling polarization diversity via an adiabatic waveguide polarization converter. When utilized in an optical system of discrete components or in a photonic integrated circuit (PIC), this adiabatic waveguide polarization converter may receive an unknown single-mode polarization of light. This light may, for example, originate from a remote location and come through a single mode fiber. As described in further detail herein, embodiments of the invention reduce the requirements and component complexity for polarization handling for polarization diversity systems.

Abstract: Embodiments of the invention describe systems, apparatuses and methods for providing athermicity and a tunable spectral response for optical filters. Finite impulse response (FIR) filters are commonly implemented in photonic integrated circuits (PICs) to make devices such as wavelength division multiplexing (WDM) devices, asymmetric Mach-Zehnder interferometers (AMZIs) and array waveguide gratings (AWGs). Athermicity of an FIR filter describes maintaining a consistent frequency transmission spectrum as the ambient temperature changes. A tunable spectral response for an FIR filter describes changing the spectrum of an FIR filter based on its application, as well as potentially correcting for fabrication deviations from the design. In addition, embodiments of the invention reduce energy dissipation requirements and control complexity compared to prior art solutions.

Abstract: The apparatus of the invention comprises a fluent material-receiving chamber, and a frame from which the chamber is pendently supported. A load cell suspends the chamber from the frame, and transmits milli-volt signals to an electronic control and display assembly where the signals translate to display indicia representative of weights of fluent material received by the chamber. The assembly, in response to the signals, displays the achievement of a threshold of a fluent material reception level, which is selective and predetermined, to halt further admittance of fluent material into the chamber, and displays an actual fluent material reception level, by the weight of the material. Flexure stabilizers are intercoupled between the chamber and the frame, to inhibit any displacement of the chamber from its vertical, pendent suspension. The method of the invention sets forth the procedural steps, in weighing fluent material, capable of practice by the inventive apparatus.

Abstract: The apparatus has a plurality of fluent-material-receiving chambers arrayed about a central, vertical pipe, and each chamber has a load beam extending therefrom. Gusset-type brackets, projecting from the pipe have slotted limbs through which the load beams pass, and opposite end of the load beams are coupled to load cells. Also, steel flexures are interposed between the limbs and the load beams pivotably to support the load beams thereon. Each beam has a counterweight fixed thereto, such counterweights being of weights which counterbalance the summed weight of its associated chamber and such components which are fixed to said chamber. Hence, weights of fluent materials introduced into the chambers can be directly read without there being a need to discount the chamber and components weight. Auger-type conveyors are provided for conducting fluent materials from each of the chambers to a blending tank. The latter has a mixing wand therein which is motor-driven to thoroughly mix the tank contents.