A management apparatus includes: a determiner configured to determine whether at least one application program is in operation in a specific state at a terminal apparatus connected to a network NW, the at least one application program being a target for control of a quality of service for communication in the network; and a termination processor configured to execute processing to terminate the control of the quality of the service for the terminal apparatus based on a determination result by the determiner being negative.

A management apparatus includes: a determiner configured to determine whether at least one application program is in operation in a specific state at a terminal apparatus connected to a network NW, the at least one application program being a target for control of a quality of service for communication in the network; and a termination processor configured to execute processing to terminate the control of the quality of the service for the terminal apparatus based on a determination result by the determiner being negative.

A network device for use with a client device and a cable modem termination system (“CMTS”), the client device being configured to run applications requiring data traffic of a first and second quality of service (“QoS”). The CMTS is configured to provide a first service flow and a second service flow to the network device. The network device provides a local area network (“LAN”) for connection to the client device and a network address translation (“NAT”). The NAT is configured to map the network device IP address to the client device IP address; divide the source ports into a first range and a low latency range; assign the respective data traffic of the applications to at least one port within the first range and to at least one port within the low latency range; and modify the low latency range of source ports based on a change in data traffic.

A network device for use with a client device and a cable modem termination system (“CMTS”), the client device being configured to run applications requiring data traffic of a first and second quality of service (“QoS”). The CMTS is configured to provide a first service flow and a second service flow to the network device. The network device provides a local area network (“LAN”) for connection to the client device and a network address translation (“NAT”). The NAT is configured to map the network device IP address to the client device IP address; divide the source ports into a first range and a low latency range; assign the respective data traffic of the applications to at least one port within the first range and to at least one port within the low latency range; and modify the low latency range of source ports based on a change in data traffic.

Communication network architectures, systems and methods for supporting a network of mobile nodes. As a non-limiting example, various aspects of this disclosure provide communication network architectures, systems, and methods for supporting a dynamically configurable communication network comprising a complex array of both static and moving communication nodes (e.g., the Internet of moving things). The communication network architectures, systems, and methods of the disclosure support flexible access and management of monitoring applications in a network of moving things.

Disclosed are various embodiments for managing radio-based private networks. In one embodiment, a request is received from an organization for a provider to provision a radio-based private network to cover a site of the organization. Equipment is preconfigured to implement the radio-based private network before shipping the equipment to the organization. A core network is provisioned for the organization.

A method is described for communication in a tactical network. A gateway is communicatively COUPLABLE to one or more tactical nodes and to one or more other gateways. The gateway is programmed to transmit information to and/or receive information from other gateways. Information exchanged includes gateway attributes, link attributes, service availability, and/or data availability. The gateway optionally provides quality of service, distributed persistence, load balancing, and/or transformation services. Services are provided in a modular, service-oriented architecture (SOA) to accommodate the addition of services and/or applications.

This disclosure describes systems, methods, and devices related to low latency preemption. A device may divide a first PPDU into a plurality of segmented PPDUs. The device may insert a plurality of time gaps between the plurality of segmented PPDUs, wherein the plurality of time gaps enable preemptive opportunities by a low latency transmitter. The device may identify a preemption request from a low latency transmitter of the one or more station devices during a first time gap between a first segmented PPDU and a second segmented PPDU. The device may preempt the second segmented PPDU based on a preemption bit in order to allow the low latency transmitter to transmit its low latency data.

This disclosure describes systems, methods, and devices related to low latency preemption. A device may divide a first PPDU into a plurality of segmented PPDUs. The device may insert a plurality of time gaps between the plurality of segmented PPDUs, wherein the plurality of time gaps enable preemptive opportunities by a low latency transmitter. The device may identify a preemption request from a low latency transmitter of the one or more station devices during a first time gap between a first segmented PPDU and a second segmented PPDU. The device may preempt the second segmented PPDU based on a preemption bit in order to allow the low latency transmitter to transmit its low latency data.

A method for identifying a network application. The method includes analyzing metadata and source code of a network application to extract a set of application tokens, generating an index document of the network application based on the set of application code tokens, wherein the index document is included in a library of index documents corresponding to a number of network applications, extracting a set of packet header tokens from a packet header of a packet in a flow, comparing the set of packet header tokens to the set of index documents to generate a number of match scores, wherein each match score represents a similarity measure between the set of packet header tokens and one index document, and determining, based on a highest match score corresponding to a particular network application, that the flow is generated by the particular network application.