An example device in accordance with an aspect of the present disclosure includes a diamond waveguide disposed on a substrate. The substrate includes a dielectric material. A tuner is to extend from the substrate, and is disposed at least in part over the waveguide. The tuner includes a tuner electrode to control a variable distance between the tuner and the waveguide to vary an effective refractive index of the waveguide.

A photonic integrated circuit includes a photonic device. The photonic device includes an input region configured to receive an input signal including a plurality of multiplexed channels. The photonic device includes a metastructured dispersive region structured to partially demultiplex the input signal into an output signal and a throughput signal. The output signal includes a channel of the multiplexed channels. The throughput signal includes the remaining channels of the multiplexed channels. The photonic device includes an output region and a throughput region optically coupled with the metastructured dispersive region to receive the output signal and the throughput signal, respectively. The metastructured dispersive region includes a heterogeneous distribution of a first material and a second material that structures the metastructured dispersive region to partially demultiplex the input signal into the output signal and the throughput signal.

A Photonic Integrated Circuit (PIC) includes N Ring and Disk type Microstructures (RDMs), N is an integer and greater than 1; at least one spare RDM, wherein each RDM operates spectrally in a periodic nature and has its spectral operation vary by temperature; and circuitry configured to handoff any of the N RDMs and the at least one spare RDM for spectral operation based on a current temperature. For the handoff, the at least one spare RDM is unlocked spectrally and is tuned and locked to a frequency of interest of a current RDM based on the temperature, and the current RDM is unlocked.

Predictive management of a network buffer is contemplated. The network buffer maybe predictively managed to control packet drop based at least in part on predicted sojourn time. The predicted sojourn time may be determined to predict time needed from an arriving packet to travel through a queue of the network buffer.

According to some embodiments, an integration system may include a source data store that contains a plurality of workloads (e.g., data packets). A processing platform may retrieve a workload from the source data store via first unikernel-based workload processing. The processing platform may then process the workload (e.g., filtering or dropping) to generate an output result and arrange for the output result to be provided to a sink destination via second unikernel-based workload processing (e.g., associated with a Linux event loop model of input output multiplexing). In some embodiments, the processing platform initially evaluates the workload in the source data store to determine if the workload meets a predetermined condition. If the workload does not meet the predetermined condition, the retrieving and arranging may be performed via container-based workload processing instead of unikernel-based workload processing.

According to some embodiments, an integration system may include a source data store that contains a plurality of workloads (e.g., data packets). A processing platform may retrieve a workload from the source data store via first unikernel-based workload processing. The processing platform may then process the workload (e.g., filtering or dropping) to generate an output result and arrange for the output result to be provided to a sink destination via second unikernel-based workload processing (e.g., associated with a Linux event loop model of input output multiplexing). In some embodiments, the processing platform initially evaluates the workload in the source data store to determine if the workload meets a predetermined condition. If the workload does not meet the predetermined condition, the retrieving and arranging may be performed via container-based workload processing instead of unikernel-based workload processing.

Examples herein relate to optical systems. In particular, implementations herein relate to an optical system including an optical transmitter configured to transmit optical signals. The optical transmitter includes a first optical source configured to emit light having different wavelengths, a waveguide, and an optical coupler configured to couple the emitted light from the first optical source to the waveguide. The optical transmitter further includes an array of two or more second optical sources coupled to the waveguide, each of the two or more second optical sources configured to be injection locked to a different respective wavelength of the emitted light transmitted via the waveguide from the first optical source. In some implementations, the first optical source is a master comb laser and the two or more second optical sources are slave ring lasers.

An example device in accordance with an aspect of the present disclosure includes a diamond waveguide disposed on a substrate. The substrate includes a dielectric material. A tuner is to extend from the substrate, and is disposed at least in part over the waveguide. The tuner includes a tuner electrode to control a variable distance between the tuner and the waveguide to vary an effective refractive index of the waveguide.

Aspects described herein include an optical apparatus comprising a multiple-stage arrangement of two-mode Bragg gratings comprising: at least a first Bragg grating of a first stage. The first Bragg grating is configured to transmit a first two wavelengths and to reflect a second two wavelengths of a received optical signal. The optical apparatus further comprises a second Bragg grating of a second stage. The second Bragg grating is configured to transmit one of the first two wavelengths and to reflect an other of the first two wavelengths. The optical apparatus further comprises a third Bragg grating of the second stage. The third Bragg grating is configured to transmit one of the second two wavelengths and to reflect an other of the second two wavelengths.

Structures for a filter and methods of fabricating a structure for a filter. The filter is coupled to a waveguide core. The filter includes a first plurality of grating structures positioned adjacent to a first section of the waveguide core and a second plurality of grating structures positioned adjacent to a second section of the waveguide core. The first plurality of grating structures are configured to cause laser light in a first portion of a wavelength band to be transferred between the first section of the waveguide core and the first plurality of grating structures. The second plurality of grating structures are configured to cause laser light in a second portion of a wavelength band to be transferred between the second section of the waveguide core and the second plurality of grating structures.