A system and method for prioritizing network traffic in a distributed environment. The system includes: a plurality of logic modules configured to receive policy data from a network device; a control processor associated with each logic module, each control processor configured to determine data associated with a traffic flow and coordinate traffic actions over the plurality of logic modules; a packet processor associated with each control processor and configured to determine a traffic action based on the traffic flow and received policy data; and at least one shaper object configured to enforce the determined traffic action. The method includes: receiving policy data from a network device; determining data associated with a traffic flow at logic modules to coordinate traffic actions of the logic modules; determining a traffic action based on the traffic flow and received policy data; and enforcing the traffic action across at least one shaper object.

Methods, apparatus and articles of manufacture for advertising network layer reachability information specifying a quality of service for an identified network flow are disclosed. Example methods disclosed herein to specify quality of service for network flows include receiving network layer reachability information including a first quality of service class specified for a first network flow, the network layer reachability information having been advertised by a first network element that is to receive the first network flow. Such example methods can also include updating an incoming packet determined to belong to the first network flow to indicate that the incoming packet belongs to the first quality of service class, the incoming packet being received from a second network element. Such example methods can further include, after updating the incoming packet, routing the incoming packet towards the first network element.

Methods and systems for providing quality of service over IP networks are disclosed. In one aspect, a flow label field of a header may be divided into first and second portions. The first portion defines a quality of service. The second portion identifies a message flow. Once the first portion defining the quality of service is established by the sending node, no nodes in the transmission path may change the quality of service value. Each node may route packets based on the quality of service field, or may modify the traffic class field of the header based on the quality of service and then route the packet based on the traffic class field. The QoS field can be used to complement a DSCP/traffic class field and provide a better mechanism for end-to-end QoS using IPv6. A service provider can use DSCP within its own administrative domain(s), and end users can set and maintain QoS using the methods described herein, thereby providing a framework for end-to-end QoS using IP packets.

Methods and apparatuses for transmitting data through a switch-based network in an in-vehicle communications network system. In an example transmission-based method, the method includes for a transmitter device generating, by a generator, a reservoir data stream (RSSj). The method also includes transmitting the reservoir data stream (RSSj) through the switch-based network. The method further includes, when a new data stream from the transmitter device to a receiver device is needed, replacing, by an injector, at least part of the reservoir data stream (RSSj) by a new data stream.

A method of dynamically routing packets to a destination node performed by a computing device is disclosed. The method includes: (1) detecting a status of a plurality of links to the destination node across a plurality of communications modalities; (2) determining a set of links to use for routing packets to the destination node based on the detected statuses; and (3) sending packets to the destination node via the determined set of links. A related computer program product, apparatus, and system are also disclosed.

Network traffic is monitored to coordinate control of data flows. Data flows between sender hosts and a receiver host are identified. A first data flow and a second data flow have respective priorities. Delay thresholds are assigned to the first data flow and second data flow based on their respective priorities. One-way delays of data packets of the first and second data flows are monitored relative to the assigned delay thresholds. Responsive to determining that the one-way delay of the first data flow's data packets exceed a first delay threshold, transmissions of the first data flow's data packets are paused for a first amount of time. Responsive to determining that the one-way delay of the second data flow's data packets exceed a second delay threshold, transmissions of the second data flow's packets are paused for a second amount of time that exceeds the first amount of time.

Embodiments are generally directed to managing power consumption of powered devices. In some embodiments, the powered devices draw power from a common source of power, which is limited. Under certain circumstances, exceeding the power limits can cause interruption of power to one or more of the devices, thus introducing a source of communication failures. To ensure reliable communications, an attempt to increase a power consumption of a first powered device in a power group is first reviewed to determine if the increase will cause a supplied power of the group to exceed a maximum power of the group. If the increase will cause the maximum power to be exceeded, the increase is modified, in some circumstances, to fit within the maximum power level. Alternatively, power consumption of a lower priority device is reduced to accommodate the requested power consumption increase.

A port resource reservation method, an electronic device, and a storage medium are disclosed. The method may include, receiving a request message for reserving a resource for traffic, and determining a mode for resource reservation according to the request message; in response to a determination that resource reservation is to be performed in an extended mode, acquiring, according to a predetermined first mapping relationship, an egress port queue corresponding to an extended priority carried in the request message, and performing resource reservation for the traffic on the egress port queue corresponding to the extended priority, wherein the first mapping relationship refers to a mapping relationship between the extended priority and the egress port queue; and acquiring a traffic identifier from the request message, and establishing a second mapping relationship, wherein the second mapping relationship refers to a mapping relationship between the traffic identifier and the extended priority.

A system for determining the servicing needs of a vehicle. In various embodiments, the system includes a remote server and a vehicle control module of the vehicle. The vehicle control module includes a first communication interface to enable communications with at least one vehicle device via a network fabric of the vehicle. The vehicle control module is configured to receive status data, from the vehicle device, relating to a performance status or operational status of the vehicle. The vehicle control module further includes a second communication interface that enables wireless communications with the remote server. The wireless communications include sending status data to the remote server. The remote server is configured to receive and interpret the status data to determine if the vehicle requires service, and send a response to the vehicle. When service is required, the response may cause the vehicle to provide a service indication.

A fabric interface, including: an ingress port to receive incoming network traffic; a host interface to forward the incoming network traffic to a host; and a virtualization-aware overload protection engine including: an overload detector to detect an overload condition on the incoming network traffic; a packet inspector to inspect packets of the incoming network traffic; and a prioritizer to identify low priority packets to be dropped, and high priority packets to be forwarded to the host.