Abstract: Systems and methods are described for IP Address allocation. A computerized method includes receiving at a wireless access gateway a request from a subscriber to connect to a network, allocating a first IP address to the subscriber from a first pool of IP addresses at the wireless access gateway, and assigning a second IP address to the subscriber from a second pool of IP addresses at the wireless access gateway when the subscriber requests a network service.

Abstract: Described herein are techniques for providing a user device with a virtualized peering emulation service using an internet protocol (IP) connection between a sensor gateway (gateway) and a remote virtualized peering emulation service device (emulation device). The gateway receives wireless signals (e.g., Bluetooth, ZigBee, Z-Wave, and/or the like) from the user device. The gateway generates a data packet comprising data indicative of the wireless signals received from the user device and sends the data packet to the emulation device through the IP connection. The gateway receives network traffic through the IP connection from the emulation device, the network traffic comprising data indicative of wireless signals from a remote user device. The gateway transmits the wireless signals from the remote user device, such that the user device can locally receive the wireless signals from the remote user device, thereby providing a virtualized peering emulation service to the user device.

Abstract: A method and system for automatically configuring and transforming a universal device into a feature specific device to provide desired network hardware functionality for a plurality of different conventionally single purpose devices. The universal device receives data configured for handling by a network hardware device capable of providing desired network hardware functionality. Based on the data received, the universal device identifies the desired network hardware functionality from network hardware functionalities. The universal device selects one or more virtual ports capable of providing the desired network hardware functionality. The universal device automatically configures and transforms itself into a feature specific device to provide the desired network hardware functionality by implementing the selected one or more virtual ports to handle the data received.

Abstract: A management system implemented in a cloud computing environment for automatically managing a plurality of Wi-Fi access points in a network can receive information from each of the plurality of Wi-Fi access points. The system can analyze the received information from each Wi-Fi access point to determine at least one operation condition of at least one Wi-Fi access and determine at least one new operation setting for the at least one Wi-Fi access point based on the analyzed information. The system can remotely configure the at least one Wi-Fi access point based on the at least one new operation setting.

Abstract: Described herein are techniques for providing centrally managed Wi-Fi using internet protocol (IP) connections between a central Wi-Fi access gateway and one or more radio nodes. The Wi-Fi access gateway establishes an IP connection with a radio node across a wide area network, wherein the radio node is configured to wirelessly connect to one or more Wi-Fi devices located near the radio node. The Wi-Fi access gateway receives Layer 2 data traffic over the IP connection, wherein the Layer 2 data traffic is associated with a Wi-Fi device from the one or more Wi-Fi devices connected to the radio node. The Wi-Fi access gateway controls one or more Wi-Fi services for the Wi-Fi device based on the Layer 2 data traffic so that the Wi-Fi access gateway can provide centrally managed Wi-Fi for the Wi-Fi device.

Abstract: Described herein are techniques for providing a virtual Wi-Fi service using internet protocol (IP) connections between a central Wi-Fi access gateway (WAG) and one or more radio nodes. The WAG establishes an IP connection with a first radio node across a network, where the first radio node is configured to connect to one or more Wi-Fi devices located near the first radio node. The WAG receives network traffic over the IP connection, where the network traffic is associated with a Wi-Fi device from the one or more Wi-Fi devices connected to the first radio node. The WAG provides a virtual Wi-Fi service through the network to the Wi-Fi device based on the network traffic such that the Wi-Fi device connects to the virtual Wi-Fi service as if the virtual Wi-Fi service is a physical device locally connected to the first radio node.

Abstract: A combination cellular and Wi-Fi hardware device has an IP interface that is configured to communicate with a first cellular network, a Wi-Fi network, or both. The combination cellular and Wi-Fi hardware device is configured to provide the network functionality (e.g., virtualized network cloud) that is required to facilitate communication and data flow between the IP interface and either a second cellular network or a cloud computing infrastructure network. The IF interface is accessed using a single IP address by a mobile device in wireless communication with the combination cellular and Wi-Fi hardware device. The single IP address is maintained when the mobile device switches between using the first cellular network and the Wi-Fi network to communicate with the combination cellular and Wi-Fi hardware device, and vice versa.

Abstract: Systems and methods are described for providing application and content awareness for self-optimizing networks. A computerized method includes receiving at a mobile gateway a session request from a mobile device, establishing a session between the mobile device and the mobile gateway, receiving a request from the mobile device at the mobile gateway to access a remote resource, establishing a connection between the mobile device and the remote resource via the mobile gateway, detecting application and content information of a service data flow of the connection, and sending the application and content information of the service data flow to a network server for network optimization.

Abstract: A computing system for processing network traffic includes a plurality of network ports configured to receive network traffic, a plurality of processing blades, not directly coupled with the plurality of network ports, configured to process the network traffic, a switch coupled with the plurality of processing blades and configured to support inter-blade communications among the plurality of processing blades, a router coupled with the switch and the plurality of network ports, the router configured to forward the network traffic to one or more of the plurality of processing blades based on resource information of the plurality of the processing blades, and a system controller coupled to the router and the plurality of processing blades, the system controller configured to receive and maintain the resource information from the plurality of the processing blades and further configured to update the router with the resource information of the plurality of the processing blades.

Abstract: A computing system for processing network traffic includes a plurality of network ports configured to receive network traffic, a plurality of processing blades, not directly coupled with the plurality of network ports, configured to process the network traffic, a switch coupled with the plurality of processing blades and configured to support inter-blade communications among the plurality of processing blades, a router coupled with the switch and the plurality of network ports, the router configured to forward the network traffic to one or more of the plurality of processing blades based on resource information of the plurality of the processing blades, and a system controller coupled to the router and the plurality of processing blades, the system controller configured to receive and maintain the resource information from the plurality of the processing blades and further configured to update the router with the resource information of the plurality of the processing blades.

Abstract: Computerized systems and computerized methods are provided for internet protocol (IP) address allocation for Wi-Fi clients in a manner that avoids assigning a public IP address to a device if the device is not first activated to use services provided by the network. A private IP network address is allocated to a device, wherein the private IP network address is only valid for a predetermined period, and only allows the device to activate itself with the network instead of providing the device full access to the network. The device is monitored during the predetermined period so that if the device is activated to use the network during the predetermined period, the computing device assigns a public IP address to the device so that the device can access a full set of services provided by the network.

Abstract: Systems and methods are described for providing cloud-based virtual local networks. A computerized method for providing cloud-based virtual local networks includes receiving at a network gateway a request for a network address from a network switch, communicating with a user device management entity (uDME) server to authorize the network switch, receiving an authorization response from the uDME server for the network switch, receiving a network address pool at the network gateway from the uDME server, and creating at the network gateway a virtual home router containing a virtual home router context that is unique to the virtual home router and associated with the network address pool.

Abstract: Systems and methods are described for extending multicast/broadcast service to wide area networks. A computerized method includes receiving a multicast/broadcast discovery message from a client, encapsulating the multicast/broadcast discovery message at a gateway, forwarding the encapsulated multicast/broadcast discovery message to a multicast/broadcast server, receiving a multicast/broadcast discovery response message from the multicast/broadcast server with a server IP address, generating a server alias IP address for the multicast/broadcast server at the gateway, replacing the server IP address with the server alias IP address in the multicast/broadcast discovery response message, encapsulating the multicast/broadcast discovery response message at the gateway, and forwarding the encapsulated multicast/broadcast discovery response message to the client.

Abstract: Systems and methods are described for providing application and content awareness for self-optimizing networks. A computerized method includes receiving at a mobile gateway a session request from a mobile device, establishing a session between the mobile device and the mobile gateway, receiving a request from the mobile device at the mobile gateway to access a remote resource, establishing a connection between the mobile device and the remote resource via the mobile gateway, detecting application and content information of a service data flow of the connection, and sending the application and content information of the service data flow to a network server for network optimization.

Abstract: Systems and methods are described for IP Address allocation. A computerized method includes receiving at a wireless access gateway a request from a subscriber to connect to a network, allocating a first IP address to the subscriber from a first pool of IP addresses at the wireless access gateway, and assigning a second IP address to the subscriber from a second pool of IP addresses at the wireless access gateway when the subscriber requests a network service.

Abstract: A computing system for processing network traffic includes a plurality of network ports configured to receive network traffic, a plurality of processing blades, not directly coupled with the plurality of network ports, configured to process the network traffic, a switch coupled with the plurality of processing blades and configured to support inter-blade communications among the plurality of processing blades, a router coupled with the switch and the plurality of network ports, the router configured to forward the network traffic to one or more of the plurality of processing blades based on resource information of the plurality of the processing blades, and a system controller coupled to the router and the plurality of processing blades, the system controller configured to receive and maintain the resource information from the plurality of the processing blades and further configured to update the router with the resource information of the plurality of the processing blades.

Abstract: A computing system for processing network traffic includes a plurality of network ports configured to receive network traffic, a plurality of processing blades, not directly coupled with the plurality of network ports, configured to process the network traffic, a switch coupled with the plurality of processing blades and configured to support inter-blade communications among the plurality of processing blades, a router coupled with the switch and the plurality of network ports, the router configured to forward the network traffic to one or more of the plurality of processing blades based on resource information of the plurality of the processing blades, and a system controller coupled to the router and the plurality of processing blades, the system controller configured to receive and maintain the resource information from the plurality of the processing blades and further configured to update the router with the resource information of the plurality of the processing blades.

Abstract: A computing system for processing network traffic includes a plurality of network ports configured to receive network traffic, a plurality of processing blades, not directly coupled with the plurality of network ports, configured to process the network traffic, a switch coupled with the plurality of processing blades and configured to support inter-blade communications among the plurality of processing blades, a router coupled with the switch and the plurality of network ports, the router configured to forward the network traffic to one or more of the plurality of processing blades based on resource information of the plurality of the processing blades, and a system controller coupled to the router and the plurality of processing blades, the system controller configured to receive and maintain the resource information from the plurality of the processing blades and further configured to update the router with the resource information of the plurality of the processing blades.