Abstract: An optical sensing module suitable for wearable devices, the optical sensing module comprising: a silicon or silicon nitride transmitter photonic integrated circuit (PIC), the transmitter PIC comprising: a plurality of lasers, each laser of the plurality of lasers operating at a wavelength that is different from the wavelength of the others; an optical manipulation region, the optical manipulation region comprising one or more of: an optical modulator, optical multiplexer (MUX); and additional optical manipulation elements; and one or more optical outputs for light originating from the plurality of lasers.

Abstract: A method of manufacturing an optoelectronic device including a mode converter. The method has the steps of: on a first silicon-on-insulator (SOI) wafer, manufacturing the optoelectronic device; and either: on a second SOI wafer, manufacturing a mode converter; and bonding the mode converter to the first SOI wafer; or bonding a second SOI wafer to the first SOI wafer to form a combined wafer; and etching a mode converter into the combined wafer.

Abstract: A silicon photonics integrated beam steering device includes a light source operably coupled to a light dispenser, a chained optical switch array including a first optical switch having a first control circuit and a second optical switch having a second control circuit, and a pixel array having a first pixel and a second pixel, wherein the light dispenser is operably coupled to first optical switch, the first optical switch is operably coupled to both the second optical switch and the first pixel, and the second optical switch is operably coupled to the second pixel, and wherein the device is configured to selectively transmit light along a plurality of optical paths to the first pixel, the second pixel, or both the first pixel and the second pixel in response to a first control voltage applied to the first control circuit and a second control voltage applied to the second control circuit.

Abstract: A method of transfer printing. The method comprising: providing a precursor photonic device, comprising a substrate and a bonding region, wherein the precursor photonic device includes one or more alignment marks located in or adjacent to the bonding region; providing a transfer die, said transfer die including one or more alignment marks; aligning the one or more alignment marks of the precursor photonic device with the one or more alignment marks of the transfer die; and bonding at least a part of the transfer die to the bonding region.

Abstract: A device coupon for use in a hybrid integration process with a silicon platform. The device coupon comprises: an input waveguide, including an input facet; an active waveguide, coupled to the input waveguide, the active waveguide including a III-V semiconductor based electro-optical device; and an output waveguide, configured to couple light between the active waveguide and an output facet. The input waveguide and output waveguide are passive waveguides.

Abstract: A coupon wafer for a micro-transfer printing process. The coupon wafer including a device coupon attached to a substrate of the coupon wafer by one or more tethers; wherein the or each tether is a pillar extending at least partially through the device coupon to contact the substrate of the coupon wafer.

Abstract: A wearable device. In some embodiments, the wearable device includes: a sensing module; and a strap attached to the sensing module, the wearable device being configured to be worn by a user, with a lower surface of the sensing module in contact with the user, the strap extending over an upper surface of the sensing module.

Abstract: A photonic chip. In some embodiments, the photonic chip includes a waveguide; and an optically active device comprising a portion of the waveguide. The waveguide may have a first end at a first edge of the photonic chip; and a second end, and the waveguide may have, everywhere between the first end and the second end, a rate of change of curvature having a magnitude not exceeding 2,000/mm2.

Abstract: A method of fabricating a device coupon including a waveguide which is suitable for use in a micro-transfer printing process. The method comprises the steps, on a wafer, of: depositing a lower cladding layer on an uppermost surface of the wafer; providing a silicon nitride guiding layer on an uppermost surface of the lower cladding; depositing an upper cladding over at least an uppermost surface of the silicon nitride guiding layer; providing a tether over the coupon, and etching away a region of the uppermost layer of the wafer located between the lower cladding layer and a substrate of the wafer, thereby leaving the lower cladding layer, silicon nitride guiding layer, and upper cladding layer suspended above the wafer via the tether.

Abstract: A method of manufacturing a III-V based optoelectronic device on a silicon-on-insulator wafer. The silicon-on-insulator wafer comprises a silicon device layer, a substrate, and an insulator layer between the substrate and silicon device layer. The method includes the steps of: providing a device coupon, the device coupon being formed of a plurality of III-V based layers; providing the silicon-on-insulator wafer, the wafer including a cavity with a bonding region; transfer printing the device coupon into the cavity, and bonding a layer of the device coupon to the bonding region, such that a channel is left around one or more lateral sides of the device coupon; filling the channel with a bridge-waveguide material; and performing one or more etching steps on the device coupon, silicon-on-insulator wafer, and/or channel.

Abstract: An electro-optically active device comprising: a silicon on insulator (SOI) substrate including a silicon base layer, a buried oxide (BOX) layer on top of the silicon base layer, a silicon on insulator (SOI) layer on top of the BOX layer, and a substrate cavity which extends through the SOI layer, the BOX layer and into the silicon base layer, such that a base of the substrate cavity is formed by a portion of the silicon base layer; an electro-optically active waveguide including an electro-optically active stack within the substrate cavity; and a buffer region within the substrate cavity beneath the electro-optically active waveguide, the buffer region comprising a layer of Ge and a layer of GaAs.

Abstract: A stamp suitable for use in a micro-transfer printing process. The stamp comprises: a carrier layer; a plurality of stamp base sections, wherein: each stamp base section is attached on a first surface to the carrier layer, and separated from each adjacent stamp base section by a gap; and each stamp base section includes one or more stamping posts, for adhering to a source coupon, each stamping post extending from a second surface of its respective stamp base section.

Abstract: An optoelectronic device. The device comprises: a silicon-on-insulator platform, including a silicon waveguide, formed in a silicon device layer, a silicon substrate, and a cavity; a III-V semiconductor based device, located within the cavity of the silicon-on-insulator platform and containing a III-V semiconductor based waveguide which is coupled to the silicon waveguide. A region of a bed of the cavity, located between the III-V semiconductor based device and the substrate, includes a patterned surface, which is configured to interact with an optical signal within the III-V semiconductor based waveguide of the III-V semiconductor based device.

Abstract: A photonic chip. In some embodiments, the photonic chip includes a waveguide; and an optically active device comprising a portion of the waveguide. The waveguide may have a first end at a first edge of the photonic chip; and a second end, and the waveguide may have, everywhere between the first end and the second end, a rate of change of curvature having a magnitude not exceeding 2,000/mm2.

Abstract: A coupon wafer comprising a device coupon (110) for use in a micro-transfer printing process used to fabricate an optoelectronic device. The coupon wafer includes a wafer substrate (124), and the device coupon (110) is attached to the wafer substrate via a tether (122) and the tether (122) is formed from a dielectric material.

Abstract: A sensor. In some embodiments, the sensor includes a first waveguide, a flexible support element, and a second waveguide. A first portion of the first waveguide may be supported by the flexible support element and separated by a first gap from a second portion of the first waveguide. The flexible support element may be capable of bending so as to cause an effective index of refraction of the first waveguide to change. The first waveguide may be coupled to the second waveguide through a second gap, the second gap being at an end of the first waveguide and an end of the second waveguide.

Abstract: A source wafer for use in a micro-transfer printing process. The source wafer comprising: a wafer substrate; a photonic component, provided in a device coupon, the device coupon being attached to the wafer substrate via a release layer; and one or more etch stop layers, located between the photonic component and the wafer substrate.

Abstract: An optoelectronic device. The optoelectronic device including: a silicon platform, including a silicon waveguide and a cavity, wherein a bed of the cavity is provided at least in part by a buried oxide layer; a III-V semiconductor-based optoelectronic component, bonded to a bed of the cavity of the silicon platform; and a bridge-waveguide, located between the silicon waveguide and the III-V semiconductor-based optoelectronic component.

Abstract: An integrated switch assembly having a stacked configuration, the integrated switch assembly comprising: a first layer, the first layer comprising a photonic integrated circuit, PIC; a second layer, the second layer comprising a switch ASIC; wherein the first layer is mounted onto a substrate and the second layer is mounted on top of the first layer.

Abstract: A waveguide platform and method of fabricating a waveguide platform on a silicon wafer; the method comprising: providing a wafer having a layer of crystalline silicon; lithographically defining a first region of the top layer; electrochemically etching the wave-guide platform to create porous silicon at the lithographically defined first region; epitaxially growing crystalline silicon on top of the porous silicon to create a first upper crystalline layer with a first buried porous silicon region underneath; wherein the first buried porous silicon region defines a taper between a first waveguide region of crystalline silicon having a first depth and a second waveguide region of crystalline silicon having a second depth which is smaller than the first depth.