A communication system includes a flow collector that collects traffic of an NW edge accommodating CPE, an NFVO that provides an instruction to add or remove a resource of a VNF, a resource management device that notifies the NFVO of an increased or decreased resource amount and an addition or removal instruction of the VNF based on an increase or decrease of the traffic of the NW edge collected by the flow collector, and that decides on the VNF which becomes a redirection destination of the traffic of the NW edge in response to execution of addition or removal of the VNF by the NFVO, a VIM that adds or removes the VNF in accordance with an instruction from the NFVO, and a flow controller that instructs the NW edge to set the VNF decided by the resource management device as the redirection destination of the traffic.

A method of communication in a vehicle network is provided. An example method includes transmitting a network allocation map in a TDMA cycle, indicating reservation of time slots in the TDMA cycle. The method further includes transmitting a synchronization signal in the TDMA cycle, to synchronize the timing of nodes in the vehicle network. Each of the reserved time slots is identified by at least a network ID of a transmitting node in the vehicle network, and a slot type comprising one of a low latency traffic slot, and a bulk traffic slot. Further, the low latency traffic slots are repeated in the TDMA cycle at least as frequently as a guaranteed QoS latency parameter. Further, the bulk traffic slots are at least as long as a guaranteed QoS throughput parameter.

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.

A de-jitter function for holding-and-forwarding packets such that the packets are delivered with an agreed fixed latency. The de-jitter function can be placed at the edge of a virtual 5G TSN switch (e.g. the de-jitter function can be deployed as part of a UPF for uplink (UL) packets and/or it can be deployed as part of a user equipment (UE) for downlink (DL) packets). By using the de-jitter function, the TSN can consider the wireless network as having a consistent, deterministic latency with no jitter.

A method for implementing data transmission of a time sensitive network (TSN) is provided. The method includes, reporting, by a session management function (SMF) device, a port number list of a device-side TSN converter to an application function device and a port number list of a network TSN converter, and receiving, by the SMF device, a port configuration parameter issued by the application function device, the port configuration parameter comprising port resources associated with a protocol data unit (PDU) session. The PDU includes a plurality of periodic time sensitive communication service data flows, The plurality of periodic time-sensitive communication service data flows have the same quality of service requirement. The plurality of periodic time-sensitive communication service data flows have the same period and the same period of service quality, the same period being a period of the plurality of periodic time-sensitive communication service data flows being the same.

Embodiments of the invention are directed to a system, method, and computer program product for processing technology resource identifiers and establishing dynamic context-based cross-network communications for resource transfer activities. The system first receives a transmission that a user has requested a resource transfer. The system then determines, based on a universal identifier associated with a second user, an identifier of a resource account associated with the second user. The system then transmits a request for the resource transfer to a resource processing system.

A method, a communication device, a computer program, and a computer program product for cyclic time-slotted operation in a wireless industrial network. The communication device includes a memory having a first memory area and a second memory area. The method includes running an application software at application layer. The application software is associated with a first pointer. The method includes operating a communication hardware at physical layer. The communication hardware is associated with a second pointer. The first pointer and the second pointer in a given timeslot point at a respective different one of the memory areas, such that in the given timeslot the application software is enabled to access one of the memory areas and the communication hardware is enabled to access the other of the memory areas. The method includes swapping the pointers to the memory areas at the end of each cycle of the cyclic time-slotted operation.

Techniques for load balancing communication sessions in a networked computing environment are described herein. The techniques may include establishing a first communication session between a client device and a first computing resource of a networked computing environment. Additionally, the techniques may include storing, in a data store, data indicating that the first communication session is associated with the first computing resource. The techniques may further include receiving, at a second computing resource of the networked computing environment, traffic associated with a second communication session that was sent by the client device, and based at least in part on accessing the data stored in the data store, establishing a traffic redirect such that the traffic and additional traffic associated with the second communication session is sent from the second computing resource to the first computing resource.

A wireless communication circuit for operating over a wireless local area network (WLAN) in which real time application (RTA) traffic and non-RTA traffic coexist and are distinguished from one another. RTA queues are created to enqueue RTA packets while non-RTA packets are pushed into non-RTA queues. Management frames containing RTA session parameters and RTA queue setting information are exchanged between stations. Channel time is allocated to RTA queues for transmitting packets, during which non-RTA queues are not allowed to access the channel. Stations determine which RTA queues to enqueue an RTA packet into based on RTA queue classification information of its RTA session.

An integrated gateway system configured to perform: receiving online data transmissions from a user computing device of a user; authenticating that a source of the online data transmissions matches the user computing device; transmitting the online data transmissions to the internal gateway system; authenticating credentials of the user as a pre-authorized user; restricting a number of incoming calls using a rate-limiting throttle system; transmitting the online data transmissions to the communication management system; batching the online data transmissions into one or more micro-batches based on one or more rules; transmitting the one or more micro-batches to one or more respective backend services using an events stream system; receiving respective responses transmitted from the one or more respective backend services in response to each one of the one or more micro-batches; performing each respective task of one or more tasks based on the respective responses from the one or more respective backend services. Other embodiments are disclosed.