Abstract: A system includes a first chiplet, a second chiplet, an electronic amplification module, and a converter module. The first chiplet includes, e.g., a network switch, a central processor unit, a graphics processor unit, a tensor processing unit, a neural network processor, an artificial intelligence accelerator, a digital signal processor, an application specific integrated circuit (ASIC), or a data storage device. The second chiplet includes a photonic module having, e.g., optical switches, optical couplers, optical routers, optical splitters, optical multiplexers, optical demultiplexers, optical filters, optical modulators, optical phase shifters, lasers, optical amplifiers, optical-to-electrical signal converters, or electrical-to-optical signal converters. The electronic amplification module includes, e.g., a driver amplifier or a transimpedance amplifier, and configured to process electrical signals sent to or from the photonic module.

Abstract: The present disclosure provides a wavelength division multiplexing (WDM) device for demultiplexing an optical signal including a plurality of wavelength channels. The device comprises at least one demultiplexer block configured to provide, for each wavelength channel of the optical signal, two half-channel signals. The device further comprises a mode mapping block configured to map one half-channel signal related to a split wavelength channel into a first polarization mode, and the other half-channel signal related to the same split wavelength channel into a second polarization mode. The device also comprises an output block for each wavelength channel, each output block being configured to combine polarized half-channel signals related to the same wavelength channel.

Abstract: The present disclosure provides a WDM, device 100 for demultiplexing an optical signal 101 including a plurality of N wavelength channels. The device 100 comprises at least one demultiplexer block 102 configured to split the optical signal into two half-channel signals 103 for each wavelength channel. The device 100 further comprises a mode mapping block 104 configured to map one half-channel signal 103 related to a split wavelength channel into a first polarization mode, and the other half-channel signal 103 related to the same split wavelength channel into a second polarization mode. The device 100 also comprises an output block 105 for each wavelength channel, which is configured to combine all polarized half-channel signals related to the same wavelength channel.

Abstract: An optical chip comprises an input edge coupler having at least one input waveguide and configured to receive light on two orthogonal modes of same polarization, a demultiplexer configured to divide the two orthogonal modes into a mode carried on a first intermediate waveguide and a mode carried on a second intermediate waveguide independent from the first intermediate waveguide, a polarization multiplexer configured to recombine the modes carried on the intermediate waveguides into two polarization-orthogonal modes carried on one output waveguide.

Abstract: An optical chip comprises an input edge coupler having at least one input waveguide and configured to receive light on two orthogonal modes of same polarization, a demultiplexer configured to divide the two orthogonal modes into a mode carried on a first intermediate waveguide and a mode carried on a second intermediate waveguide independent from the first intermediate waveguide, a polarization multiplexer configured to recombine the modes carried on the intermediate waveguides into two polarization-orthogonal modes carried on one output waveguide.

Abstract: An optical coupling arrangement is provided, comprising a lightwave circuit (LC), a coupling element and an optical waveguide element, wherein the lightwave circuit has a first surface area and wherein the coupling element is attached to the first surface area) such that an optical signal can be transmitted from the lightwave circuit to the coupling element. The optical waveguide element is attached to the coupling element at a first junction zone such that the optical signal can be transmitted from the coupling element to the optical waveguide element). The coupling element is configured to perform mode transformation to the optical signal transmitted from the lightwave circuit to the optical waveguide element and such that adiabatic coupling of the optical signal to the optical waveguide element is enabled. Thus, a better coupling efficiency can be achieved.

Abstract: An optical coupling arrangement is provided, comprising a lightwave circuit (LC), a coupling element and an optical waveguide element, wherein the lightwave circuit has a first surface area and wherein the coupling element is attached to the first surface area) such that an optical signal can be transmitted from the lightwave circuit to the coupling element. The optical waveguide element is attached to the coupling element at a first junction zone such that the optical signal can be transmitted from the coupling element to the optical waveguide element). The coupling element is configured to perform mode transformation to the optical signal transmitted from the lightwave circuit to the optical waveguide element and such that adiabatic coupling of the optical signal to the optical waveguide element is enabled. Thus, a better coupling efficiency can be achieved.

Abstract: The present invention provides a waveguide structure for optical coupling. The waveguide structure includes a first waveguide embedded in a cladding of lower refractive index than the first waveguide, and a second waveguide of higher refractive index than the cladding and distanced from the first waveguide. The waveguide structure further includes an intermediate waveguide, of which at least a part is arranged between the first waveguide and the second waveguide. The first waveguide and the second waveguide each comprise a tapered end for coupling light into and/or out of the intermediate waveguide.

Abstract: A polarization splitter and rotator device includes an optical mode converter comprising a first optical waveguide, wherein a core of the first optical waveguide is asymmetrically shaped; and an output coupler comprising a second optical waveguide coupled to the first optical waveguide and a third optical waveguide adiabatically coupled to the second optical waveguide, the adiabatically coupling provoking the polarized light coupled from the first optical waveguide into the second optical waveguide to spread its power between the second optical waveguide and the third optical waveguide by coupling its transverse electric mode of first order as transverse electric mode of zeroth order into the third optical waveguide and keeping its transverse electric mode of zeroth order propagating in the second optical waveguide without coupling to the third optical waveguide.

Abstract: The present invention provides a waveguide structure for optical coupling. The waveguide structure includes a first waveguide embedded in a cladding of lower refractive index than the first waveguide, and a second waveguide of higher refractive index than the cladding and distanced from the first waveguide. The waveguide structure further includes an intermediate waveguide, of which at least a part is arranged between the first waveguide and the second waveguide. The first waveguide and the second waveguide each comprise a tapered end for coupling light into and/or out of the intermediate waveguide.

Abstract: The invention relates to a temperature insensitive semiconductor laser, comprising: a gain region for generating laser radiation; a reflector region for reflecting the laser radiation generated in the gain region, and a waveguide for guiding the laser radiation generated in the gain region to the reflector region and for guiding the laser radiation reflected in the reflector region to the gain region, wherein the gain region, the reflector region and the waveguide define a resonating cavity of the semiconductor laser and wherein the waveguide is substantially athermal.

Abstract: A coupler/splitter including two neighboring coplanar waveguide portions extending in a same direction, the first portion having a constant cross-section, the second portion having a variable cross-section so that the effective index of the second waveguide portion varies, in the upstream-to-downstream direction, from a first lower value to a second value higher than the effective index of the first portion, in adiabatic coupling conditions.

Abstract: A coupler/splitter including two neighboring coplanar waveguide portions extending in a same direction, the first portion having a constant cross-section, the second portion having a variable cross-section so that the effective index of the second waveguide portion varies, in the upstream-to-downstream direction, from a first lower value to a second value higher than the effective index of the first portion, in adiabatic coupling conditions.