Techniques are described for prioritized establishment of communication sessions. In one example, a network device parses a configuration file that defines a plurality of communication sessions of a routing protocol and includes priority values assigned to the communication sessions. The network device creates two or more lists of communication sessions for two or more of the priority values based on the configuration file, wherein each list of the two or more lists is created for a particular priority value of the priority values and defines one or more communication sessions of the plurality of communication sessions that are assigned the particular priority value. The network device then establishes the one or more communication sessions included in each list of the two or more lists according to an ordering based on the priority values associated with the two or more lists.

A resource host transmits a payload to a client device. The payload includes a first asset hosted by the resource host, and the first asset is associated with a first reference tag indicating a versioning status of the first asset. The resource host receives an Add Ref Instruction, wherein the Add Ref Instruction, which includes a custom reference tag indicating a user-selected versioning status of the first asset. The resource host associates a second reference tag with the first asset based on the custom reference tag.

Techniques are disclosed for allocating shared resources to nodes in a distributed computing network system. Nodes request a lock for each instance of a computing resource (e.g., a virtual IP address associated with a service provided by the distributed computing network system) from a distributed lock manager. The distributed lock manager maintains a queue of requests for each instance of the shared resource. Upon receiving a lock from the distributed lock manager, the receiving node performs a fairness allocation protocol to determine whether to accept the lock. If so determined, the shared computing resources associated with the lock is configured.

A method for distributing data process according to technical resource capacity availability and constraints across a network is disclosed. The method includes receiving, at a database, a feed request for processing by a computing resource, among a network of computing resources that are geographically dispersed. Further, the method includes identifying, among the network of computing resources, a computing resource for processing the feed request based on the at least one attribute and processing capacity of the computing resources, and assigning the feed request for processing to the identified computing resource in real-time and without predetermined assignment to process increase in data volume by leveraging remotely located and/or underutilized computing resources.

An electrical computer system processing architecture for providing an indication of activity in the electrical computer system, the electrical computer system processing architecture comprising a plurality of client computers connected to at least one server by a computer network. Each of the client computers is configured to provide requests to the at least one server. The or each server comprises a store for storing requests provided by the plurality of client computers. The or each server is configured to match complementary requests from the plurality of client computers stored in the store. Following the matching of complementary requests, the or each server counts unmatched requests corresponding to one or other of the complementary requests in the store, and outputs the counted number of unmatched requests to provide the indication of activity in the computer system.

The present disclosure is directed to methods and systems for distributing network connectivity from a gateway. The network access system can include a gateway with the ability to support regulating network access to various devices. The network access functionality can be configurable and customizable to various users or devices. The gateway can connect to a source and determine the bandwidth. Using the determined bandwidth, the gateway can allocate the bandwidth among the devices according to a priority order of the devices. In some implementations, the gateway can receive customizable features from the user for bandwidth allocation to devices connected the gateway. The gateway can track the network usage by MAC address of a device and disconnect the device from the network when the network usage reaches a threshold.

A method for execution in a central controller comprises obtaining an interconnection topology for a plurality of nodes interconnected via hybrid data/power links; obtaining a power distribution map associated with the topology; and causing DC power to be distributed to the nodes via the links according to the power distribution map. Also, such a node in which there is at least one power-receiving port and at least one power-transmitting port, a controller and power switching circuitry. The controller operates based on power drawn from a portion of the DC power received via the power-receiving port. The controller determines a destination of data packets received via any of the ports and outputting those of the received data packets that are not destined for the network device via another one of the ports. The controller also causes the power switching circuitry to output via plural power-transmitting ports respective portions of the received DC power received at the power-receiving port.

The present disclosure is directed to methods and systems for providing multiple networks from a gateway. A multiple network gateway system can include a gateway (e.g., a router) with the ability to support multiple, configurable, and customizable networks. The gateway can connect to a source (e.g., internet service provider (ISP), cable networks, OTA networks, satellite networks, etc.) and determine the bandwidth. Using the determined bandwidth, the gateway can allocate the bandwidth among the multiple networks according to a priority order of the networks. In some implementations, the gateway can receive customizable features from the user. Examples of the customizable features can include security options, parental controls, operational hours, MAC address specific operations, number of user limits, and internet usage tracking. The gateway can determine the priority of each network based on the customizable features.

Gateway apparatus and methods for providing data services (including IoT data services) which leverage existing managed network (e.g., cable network) infrastructure. The disclosed methods and apparatus enable, among other things, delivery of IoT data services in a unified manner via a common portal or IoT gateway (IoTG) which may be both remotely accessed by a user, and remotely controlled/configured by the host network operator (e.g., MSO). In one variant, the premises devices include RF-enabled receivers (enhanced consumer premises equipment, or CPEe) configured to receive (and transmit) OFDM waveforms via a coaxial cable drop to the premises, and interface with the aforementioned IoTG to enable provision of both 5G high-speed data services and lower bandwidth IoT services to the premises, all via a single coaxial cable drop in the exemplary embodiment.

An operation method of a first end node constituting an Ethernet-based vehicle network includes receiving a first beacon from a second end node, the beacon including first configuration information of a first main-cycle including a plurality of sub-cycles each of which includes N time slots; transmitting a signal in a time slot corresponding to an identifier of the first end node among the N time slots within a sub-cycle #k of the plurality of sub-cycles; and transmitting a signal in a time slot corresponding to the identifier of the first end node among the N time slots in a sub-cycle #(k+1) consecutive with the sub-cycle #k of the plurality of sub-cycles.