The present invention discloses a method and an apparatus for establishing a link between virtualized network functions. The method includes obtaining an internet protocol (IP) address of a connection point (CP) of a first virtualized network function (VNF) and identification information of the CP. The method also includes determining identification information of a second VNF corresponding to the identification information of the CP of the first VNF, sending the IP address of the CP of the first VNF and the identification information of the CP to the second VNF corresponding to the identification information of the second VNF. Additionally, the method includes starting a link connection establishment process between a CP of the second VNF and the CP of the first VNF.

A new host is detected being added to a network cluster, wherein each of a plurality of hosts are on the network cluster. Available interfaces on each of the plurality of hosts on the network cluster are detected responsive to detecting the new host being added. A classless inter-domain routing (CIDR) range is calculated for hosts and interfaces on the network cluster using the available interfaces. Pod routes with interface range and L3 host routes are set for each host.

A new host is detected being added to a network cluster, wherein each of a plurality of hosts are on the network cluster. Available interfaces on each of the plurality of hosts on the network cluster are detected responsive to detecting the new host being added. A classless inter-domain routing (CIDR) range is calculated for hosts and interfaces on the network cluster using the available interfaces. Pod routes with interface range and L3 host routes are set for each host.

A system that enables end-user devices that operate within different enterprise networks to exchange data with one another. In particular, the disclosed system uses unique IP addresses that are dedicated solely to supporting a predefined communication service between enterprise computer networks, in order to identify and route each data packet according to the communications service. As part of the communications service, the data packets are transmitted, for example, from a first local service provider network hosting a first enterprise network, through a participating backbone service provider network on the public Internet and based on deterministic routing, and to a second local service provider network hosting a second enterprise network. In handling the data packets in this way, the disclosed system creates an Internet wide-area-network (WAN): the data packets are transmitted over the Internet and conceivably over a large geographic distance between enterprise networks.

The present invention provides a network system of a railcar, the network system being capable of efficiently performing maintenance work. One example of the network system of the railcar of the present invention includes: intra-car networks (N1 to N3) to which first and second apparatuses are connected; an inter-car network (NA) for transmission of information between the apparatuses mounted on different cars; routers (R1 to R3) each provided and connected between the corresponding intra-car network (N1 to N3) and the inter-car network (NA) and each including a network address translation portion configured to mutually convert a private address of the first apparatus and an IP address of the inter-car network (NA); and a maintenance transmission path forming unit configured to form a transmission path through which the transmission and reception of the information are performed between a maintenance terminal (5) and a maintenance target apparatus selected from the first and second apparatuses, the transmission path not passing through the network address translation portion of the car on which the maintenance target apparatus is mounted.

Systems, methods and devices for location-based services are disclosed in the present invention. A multiplicity of network devices, a database, and a server platform in network-based communication. The database stores a space-network model binding IP addresses and physical locations. The server platform is operable to generate at least one geofence in the space-network model and specify entitlements for the location-based services within the at least one geofence. The at least one geofence and specific entitlement are stored to the database. The multiplicity of network devices is configured to learn the space-network model and the at least one geofence and perform tasks based on the entitlements specified for the location-based services within the at least one geofence.

Systems, methods and devices for location-based services are disclosed in the present invention. A multiplicity of network devices, a database, and a server platform in network-based communication. The database stores a space-network model binding IP addresses and physical locations. The server platform is operable to generate at least one geofence in the space-network model and specify entitlements for the location-based services within the at least one geofence. The at least one geofence and specific entitlement are stored to the database. The multiplicity of network devices is configured to learn the space-network model and the at least one geofence and perform tasks based on the entitlements specified for the location-based services within the at least one geofence.

Systems, methods, and computer-readable media provide for collection of statistics relating to network traffic between virtual machines (VMs) in a network. In an example embodiment, a virtual switch hosted on a physical server provides network address information of VMs deployed on the physical server to a virtual switch controller. The controller collects this network address information from each virtual switch under its control, and distributes the aggregate address information to each switch. In this manner, the controller and each switch within the controller's domain can learn the network address information of each VM deployed on physical servers hosting switches under the controller's control. Each virtual switch can determine a classification of a frame passing through the switch (e.g., intra-server, inter-server and intra-domain, or inter-domain traffic), and statistics relating to the traffic. In an example embodiment, the virtual switch controller can collect the statistics from each switch within its domain.

An optical Internet Protocol (IP) router serves a cell-site over an optical communication network. The optical IP router transmits a network attach request having an optical node name over a control optical wavelength. The optical communication node receives an assignment of a data optical wavelength, a cell-site mode, and an Internet Protocol (IP) address over the control optical wavelength based on the optical node name. The optical communication node operates in the cell-site mode and responsively exchanges cell-site data having the IP address over the data optical wavelength.

In an example embodiment, A PICNEEC is provided. It includes one or more Virtual Customized Rules Enforcer (VCRE) instances, each VCRE instance corresponding to a group of mobile devices and defining a set of policies personalized for the group of mobile devices. Each VCRE is configured to, upon receiving a data packet communicated between a packet-based network and a mobile device in the corresponding group via a radio network, execute one or more policy rules stored in the VCRE instance to the data packet prior to forwarding the data packet. Each VCRE instance is controlled independently of one another via direct accessing of the VCRE instance by a different customer of the mobile network provider.