A network card has a plurality of buffers each having different physical performances including a memory access speed or a storage capacity, and a buffer control circuit selects one buffer to be a packet storage destination from among the plurality of buffers on the basis of a priority or a service quality of a packet specified from header information of the packet received by a physical port and the physical performances of the plurality of buffers.

Monitoring an operational characteristic of a data communication device within a network includes sampling an operational characteristic of the data communication device at a fine-grain sample rate over a first sampling interval to produce fine-grain samples of the operational characteristic of the data communication device, training a machine learning algorithm using the fine-grain samples of the operational characteristic of the data communication device, the fine-grain sample rate, and a coarse-grain sample rate that is less than the fine-grain sample rate, sampling the operational characteristic of the data communication device at the coarse-grain sample rate over a second sampling interval to produce coarse-grain samples of the operational characteristic of the data communication device, and using the machine learning algorithm to process the coarse-grain samples of the operational characteristic of the data communication device to produce accuracy-enhanced samples of the operational characteristic of the data communication device.

Embodiments of the present disclosure describe methods, apparatuses, storage media, and systems for routing data packets in a quality of service (QoS) enabled content-based network or interconnect fabric. Various embodiments describe how to manage data flow based on content-based attribute vectors (AVs) indicating QoS requirements with respect to the data packets in networking or platform interconnects. A dynamic scheduling based on AV information may improve trafficking efficiency and optimize system performance.

A gateway device for a fire control system is described herein. The gateway device can comprise a processor and a memory having instructions stored thereon which, when executed by the processor, cause the processor to detect that a network interface of the gateway device is connected to a network, receive data associated with the fire control system, and determine a data management scheme for the gateway device based on the type of detected network interface and the received data.

In various implementations, provided are systems and methods for an integrated circuit including a completer device, a requester device, and an interconnect fabric. The requester device is configured to generate transactions to the completer device, where each transaction includes a request packet that includes an attribute associated with the completer device; and the interconnect fabric is coupled to the requester device and the completer device. The integrated circuit can also include a QoS regulator configured to identify, based on a first attribute associated with the completer device, a first QoS value establishing a first priority level for a first request packet generated by the requester device, and modify the first request packet to include the first QoS value.

Technologies for accelerating edge device workloads at a device edge network include a network computing device which includes a processor platform that includes at least one processor which supports a plurality of non-accelerated function-as-a-service (FaaS) operations and an accelerated platform that includes at least one accelerator which supports a plurality of accelerated FaaS (AFaaS) operation. The network computing device is configured to receive a request to perform a FaaS operation, determine whether the received request indicates that an AFaaS operation is to be performed on the received request, and identify compute requirements for the AFaaS operation to be performed. The network computing device is further configured to select an accelerator platform to perform the identified AFaaS operation and forward the received request to the selected accelerator platform to perform the identified AFaaS operation. Other embodiments are described and claimed.

The present invention relates to a method and an apparatus for controlling the traffic of a terminal in a mobile communication system and, more particularly, to a method and an apparatus for controlling the traffic of a terminal in consideration of the quality of experience of the terminal within a wireless network. A method for controlling the traffic of a terminal in a mobile communication system, according to one embodiment of the present invention, comprises the steps of: determining whether service congestion has occurred in a wireless network based on user experience quality information on each service of at least one terminal and status information in the wireless network; and controlling traffic of the at least one terminal based on services used by terminals in the wireless network if it is determined that the service congestion has occurred in the wireless network.

A data processing method, a server, and a data collection device are provided. The method includes: obtaining, by a server, first network key performance indicator KPI data and performance data of a first set-top box STB, where the first network KPI data is network KPI data of a first video service stream, and the first STB is an STB that receives the first video service stream; and calculating, by the server, first video quality of experience QoE of the first video service stream based on an associated model, the first network KPI data, and the performance data of the first STB, where the associated model is a model obtained through training based on historical data, and the associated model is used by the server to calculate video QoE based on network KPI data and performance data of an STB.

An example programmable integrated circuit (IC) includes a processor, a plurality of endpoint circuits, a network-on-chip (NoC) having NoC master units (NMUs), NoC slave units (NSUs), NoC programmable switches (NPSs), a plurality of registers, and a NoC programming interface (NPI). The processor is coupled to the NPI and is configured to program the NPSs by loading an image to the registers through the NPI for providing physical channels between NMUs to the NSUs and providing data paths between the plurality of endpoint circuits.

A device and method and system for dynamically processing a random access response (RAR) signal to perform wireless communications is disclose. In some embodiments, the device is configured to receive one or multiple random access response (RAR) signals, wherein when the processor receives multiple RAR signals, it selects a RAR signal and responses to the selected RAR signal based on a content of the one or multiple RAR signals and proceeds with subsequent wireless communication using information contained in the selected RAR signal.