The wavelength response of an arrayed waveguide grating can be tuned, in accordance with various embodiments, using a beam sweeper including one or more heaters to shift a lateral position of light focused by the beam sweeper at an interface of the beam sweeper with an input free propagation region of the arrayed waveguide grating.

Light from discrete red, blue, and green lasers are combined into a single output using a planar lightwave circuit (PLC). In some embodiments some light from an output of the PLC is reflected back to the lasers, and in some embodiments the reflected light is primarily of one of the red, green, or blue wavelengths. In some embodiments multiple lasers of slightly differing wavelengths are provided as light sources for some or all of the red, blue, and green light.

Aspects of the subject disclosure may include, for example, a process that provides a semiconductor substrate and forms repeating, conductive patterns configured for coupling to active circuitry. Each pattern comprises a group of thermally conductive layers, wherein the group of thermally layers is thermally coupled to a thermal source generated by the active circuitry. Thermally conductive vias interconnect the group of thermally conductive layers, wherein a combination of the vias and the group of thermally conductive layers is configured to transfer heat from the thermal source with a desired directionality. The first repeating patterns are thermally coupled to each other to combine the desired directionality of each of the patterns, wherein the combination results in a distributed directionality of the heat from the thermal source thereby reducing a localized concentration of the heat. Other embodiments are disclosed.

The wavelength response of an arrayed waveguide grating can be tuned, in accordance with various embodiments, using a beam sweeper including one or more heaters to shift a lateral position of light focused by the beam sweeper at an interface of the beam sweeper with an input free propagation region of the arrayed waveguide grating.

An apparatus that includes one or more electrical or optical I/O ports that interface to external communication equipment, one or more optical ports that interface to an optical transport network that carries wavelength-division-multiplexed (WDM) optical signals, one or more tunable optical transceivers, and packet switching logic. The apparatus is configured to perform packet processing operations for ingress and egress data frames or packets. The apparatus can further include control circuitry that can take part in an automatic provisioning process that configures the tunable optical transceiver units of the network device, specifically configuring the optical channels/wavelengths of the optical signals that are transmitted by the tunable optical transceivers. The apparatus can also implement a method of processing and/or managing the optical channels/wavelengths of the optical signals that are transmitted by the tunable optical transceivers based upon the destination address of ingress data frames or packets. Multiple units can interface to the optical transport network for communication of optical packet data between the units over the optical transport network as described herein.

A method for monitoring optical fiber temperature includes heating an optical fiber using a heat source, and measuring an infrared radiation level emitted by an optical fiber during heating of the optical fiber. The method further includes comparing the infrared radiation level to a radiation level setpoint for the optical fiber to determine a radiation level error value. The method further includes adjusting a power level setpoint of the heat source based on the radiation level error value.

The wavelength response of an arrayed waveguide grating can be tuned, in accordance with various embodiments, using a beam sweeper including one or more heaters to shift a lateral position of light focused by the beam sweeper at an interface of the beam sweeper with an input free propagation region of the arrayed waveguide grating.

Provided is an optical waveguide circuit avoiding the difficulty of the property compensation based on temperature control, compensated with respect to the property variations due to fabrication error, particularly paid attention in a silicon waveguide, and being low in power consumption and high in performances. The optical waveguide circuit includes a silicon (Si) substrate, a buried oxide film (BOX) layer formed on the Si substrate, and an SOI (Silicon on Insulator) layer, formed on the BOX layer, including an optical element utilizing the SOI layer as a main optical transmission medium. At least part of a waveguide of the optical element includes uniformly distributed and thermally unstable crystal defects.

The wavelength response of an arrayed waveguide grating can be tuned, in accordance with various embodiments, using a beam sweeper including one or more heaters to shift a lateral position of light focused by the beam sweeper at an interface of the beam sweeper with an input free propagation region of the arrayed waveguide grating.

An apparatus for alleviating a nonlinear temperature effect of an arrayed waveguide grating, comprising an integrated optical circuit base for an arrayed waveguide grating chip and an actuator. The integrated optical circuit base includes a first region, a second region connected by a hinge. The actuator includes two or more actuating rods having a thermal expansion coefficient different from that of the integrated optical circuit base. In different temperature ranges, the first region and the second region are driven by different actuating rods to rotate and/or translate relative to each other, so that the first region and the second region have a nonlinear displacement as the temperature changes, which brings the two parts of the arrayed waveguide grating chip to move relative to each other to accurately compensate drifting of a central wavelength of the arrayed waveguide grating chip in the different temperature ranges.