Patent application number | Description | Published |
20110255537 | Controlling Directional Asymmetricity in Wide Area Networks - In one embodiment a method includes detecting, at a first Wide Area Network (WAN) device deployed at an edge of a WAN, a packet passing through the first WAN device and departing a node with which the first WAN device is associated for another node connected to the WAN, identifying, by the first WAN device, a network destination address to which the packet is addressed, obtaining from memory accessible to the first WAN device an identifier of another WAN device associated with the network destination address, and marking the packet with the identifier to generate a marked packet. The marked packet is then received by a WAN device, which detects the identifier, and passes the marked packet to the identified WAN device. In an embodiment, the WAN device associated with the network destination address is a WAN device that first detects a synchronization-acknowledgement (SYN-ACK) packet. | 10-20-2011 |
20130283041 | SERVER CERTIFICATE SELECTION - In one implementation, a network device, which may be a wide area network (WAN) optimization device includes a memory, a communication interface, and a processor. The memory is configured to store a pool of server certificates. The communication interface is configured to receive a data flow for optimization by the network device. The processor is configured to access a reverse domain name lookup on a destination internet protocol (IP) address extracted from the data flow to receive a fully qualified domain name (FQDN). A matching server certificate is selected from the pool of server certificates that best matches the FQDN. The common name of the matching server certificate and the FQDN are not exact matches. Instead, the common name may be the longest string match available from the pool of certificates, or the common name may have the most address components in common out of the available pool of certificates. | 10-24-2013 |
20140089500 | LOAD DISTRIBUTION IN DATA NETWORKS - Provided are methods and systems for load distribution in a data network. A method for load distribution in the data network may comprise retrieving network data associated with the data network and service node data associated with one or more service nodes. The method may further comprise analyzing the retrieved network data and service node data. Based on the analysis, a service policy may be generated. Upon receiving one or more service requests, the one or more service requests may be distributed among the service nodes according to the service policy. | 03-27-2014 |
20150281087 | FORWARDING DATA PACKETS USING A SERVICE-BASED FORWARDING POLICY - Methods and systems are provided for forwarding data packets in a service network using a service-based policy. A gateway node may receive data packets from a service session and send the data packets for a forwarding node. The forwarding node may match the service session data packet against a service address and forwarding policy, the forwarding policy being based on capabilities and service configurations of the servicing nodes in the service network. Forwarding node may then forward the service session data packet to a servicing node in accordance with the forwarding policy, and send the service session data packet to a server for processing. | 10-01-2015 |
20150312092 | ENABLING PLANNED UPGRADE/DOWNGRADE OF NETWORK DEVICES WITHOUT IMPACTING NETWORK SESSIONS - Exemplary embodiments for enabling planned network changes such as an upgrade or downgrade of a network device are disclosed. The systems and methods provide for planned upgrades and downgrades for network devices without impacting existing network sessions, by utilizing two network devices simultaneously, and creating a redirect network session for a predetermined period of time. In so doing, all network traffic may be gradually transferred to the second network device, until the sessions processed by the first network device time out. The first network device can then be taken offline for upgrade or downgrade, without any disruption to the network service or loss of network traffic. | 10-29-2015 |
20150312322 | DISTRIBUTED HIGH AVAILABILITY PROCESSING METHODS FOR SERVICE SESSIONS - Provided are methods and systems for processing a data packet associated with a service session. The data packet directed to a first servicing node can be received by a forwarding node. The forwarding node can determine that the first servicing node is unavailable. Based on the determination, the forwarding node can select a second servicing node from a plurality of servicing nodes. The selection can be based on a high availability policy. The forwarding node can then send the data packet to the second servicing node. | 10-29-2015 |
20150333988 | DISTRIBUTED SYSTEM TO DETERMINE A SERVER'S HEALTH - Exemplary embodiments for a distributed system for determining a server's health are disclosed. The systems and methods provide for a network controller to direct one or more servicing nodes to check the health of one or more servers, and report a health score to the network controller. The network controller may then calculate, update and maintain a health score for each server in the network from the various health scores reported to it from the servicing nodes. This allows a distributed system to be used to facilitate network operations, as a single device is not relied on for periodically determining each server's health. | 11-19-2015 |
20160042014 | DISTRIBUTED DATABASE IN SOFTWARE DRIVEN NETWORKS - Provided are methods and systems for implementing a distributed database in a data network. The method comprises receiving node data associated with one or more nodes of a plurality of nodes, updating the distributed database and replicating the distributed database to each of the plurality of nodes. The plurality of nodes comprises one or more cluster device, a cluster master, a traffic classification engine, a service node, and an orchestrator. The node data comprises node health, a number of total connections, node processing unit utilization, node memory status, destination server address, destination server capacity, destination server network connectivity, node dynamic state, node responsiveness. The distributed database comprises tables containing traffic map, node health information, traffic classification mapping, and service policy. | 02-11-2016 |
20160043901 | GRACEFUL SCALING IN SOFTWARE DRIVEN NETWORKS - Provided are methods and systems for graceful scaling of data networks. In one example, an indication of removal of a node from a plurality of nodes of the data network is received. A service policy is generated to reassign service requests associated with the node to another node in the plurality of nodes. The service policy is then sent to each of the plurality of nodes of the data network. To scale out a data network, an indication of presence of a further node in the data network is received, and a further node service policy is generated and sent to each of the plurality of nodes of the data network and to the further node. Additional actions can be taken in order to prevent interruption of an existing heavy-duty connection while scaling the data network. | 02-11-2016 |
20160044095 | DISTRIBUTING SERVICE SESSIONS - Provided are methods and systems for distributing service sessions from a client device in a service data network. A packet of the service session is received by a forwarding node. The forwarding node determines whether the packet matches a service address associated with the service session. Responsive to the determining, a servicing node associated with the service address is selected based on a forwarding policy. The packet is sent to the selected servicing node. The servicing node determines whether the packet is a service request packet. A server is selected based on a service policy, wherein the server is configured to serve the service session. The packet is sent to the server. Before being received by a forwarding node, the packet is received by a gateway node. The gateway node determines whether the packet matches the service address and selects the forwarding node based on a notification. | 02-11-2016 |