An intelligent wireless broadband network and content delivery management within a network includes at least one datacenter, at least one network tower and a plurality of smart nodes may be provided. Each of the plurality of smart nodes may be deployed as a micro point of presence (micro POP) at the at least one datacenter the at least one tower and at each of a plurality of hub-homes within the network. An artificial intelligence (AI) capable compute unit may be configured to provide customization of the plurality of smart nodes based on usage pattern of the plurality of homes at a neighborhood level, and thereby facilitating a dynamic edge network distribution solution for better Internet experience to the end-users.

An example server to process onboarding includes a communication interface unit, a memory to store instructions, and a processor. The processor is to execute instructions stored in the memory to receive information on a user interface screen for onboarding from a client device through the communication interface unit, and transmit information for generating a next user interface screen to be displayed on the client device to the client device through the communication interface unit based on the received information on the current user interface screen and information on a process of the onboarding.

An attractive service is provided by freely mutually connecting existing IoT devices in a silo state for each private cloud via the Internet. An IoT connection system includes an IoT hub that is realized over a cloud and a local IoT router that is connected to the IoT hub. The IoT hub includes at least one of a first driver configured to connect the IoT hub to a private cloud to which a first device is able to be connected and a second driver configured to connect a second device to the IoT hub. The IoT router includes a third driver configured to connect a third device to the IoT router. The IoT router is an information processing terminal that is able to communicate with a predetermined base station. The third device is connected to the IoT hub using a tethering function of the IoT router in a specific situation.

Present disclosure relates to system and method for providing SIP trunk service to at least one telephone system by an application server over a network, comprising establishing a connection between at least one telephone system and a first network entity via a first access node, and availing at least one SIP trunk service. Next, the at least one telephone system dynamically checks connectivity with the first network entity. The at least one telephone system establishes a connection with a second network entity via a second access node, in an event the connectivity with the first network entity fails and transmits a signal request to the application server. The application server processes the signal request and provides the at least one SIP trunk service to the at least one telephone system.

An access control method. A BNG CP may receive a first message from first user equipment. The first message is used by the first user equipment to request to access a network, a primary gateway through which the first user equipment accesses the network is a first BNG, and a backup gateway through which the first user equipment accesses the network is a second BNG. After receiving the first message, the BNG CP may determine, from a first network segment, an IP address assigned to the first user equipment, and send the IP address of the first user equipment to the first user equipment. The first network segment is only used to assign an IP address to user equipment that accesses the network by using the first BNG as a primary gateway and the second BNG as a backup gateway.

According to some embodiments, a method performed by a first software defined wide area network (SD-WAN) edge router communicably coupled to a public network comprises: receiving a transport location (TLOC)-extension configuration for a known interface of the first edge router; detecting a second edge router attempting to connect to the known interface of the first edge router; and transmitting, to the second edge router, configuration information for the second edge router so that the second edge router is able to communicate with the public network through a TLOC-extension with the first edge router. In some embodiments, the second edge router receives device configuration information (e.g., PnP, ZTP, etc.) from the public network via the TLOC-extension.

The present disclosure provides a global communication network system based on a micro base station and edge computing, including at least one micro base station. Each micro base station includes an edge computing center, a business network element and a micro base station access network. The comprehensive carrying capability of a wireless network, the regional resource sharing capability, the computing capability of an access terminal, the flexible application capability of the access terminal and user experience of extremely low delay are improved.

A method includes a proxy device receiving from a source device a request to establish a flow to a destination device; generating, based on the request, a meta-packet that indicates that the flow to the destination device is to be proxied; determining whether a pre-established flow connecting the proxy device to another proxy device that leads toward the destination device exists; sending the meta-packet on the pre-established flow, when it is determined that the pre-established flow exists; receiving by the other proxy device, the meta-packet, and establishing the flow to the destination device based on the meta-packet, where the proxy devices assign one or more of a source address, a source port, a destination address, or a destination port, associated with the source device and the destination device, to the pre-established flow.

A message communication system such as a security system having a distributed architecture includes a plurality of customer terminals (1.134.1 1.134.4), one or more proprietary routers (1.122.1 1.122.4), one or more automation systems (1.104.1 1.104.2), each customer terminal being associated with an associated at least one of the automation systems, wherein each customer terminal includes at least one communication address of at least one of the proprietary routers, the proprietary router including a routing table to forward the message to the associated automation system or a central station gateway (2.108.1) linked to the automation system.

A computer-implemented method when executed by data processing hardware of customer premises equipment installed at an exterior portion of a premises of a user causes the data processing hardware to perform operation. The operations include receiving, via a local area network associated with the user, a first communication from a user device located within an interior of the premises of the user. The operations also include receiving, via a low-power wide area network, a second communication from a low-power device located exterior of the premises of the user. The operations also include transmitting, via a broadband connection using a fixed wireless access network, the first communication and the second communication to a remote server.