49 results about "Router architecture" patented technology

An embodiment of the exemplary SoftRouter architecture includes two physically separate networks, a control plane network and a data plane network. The data plane network is one physical network for the data traffic, while the control plane network is another physical network for the control traffic. The topology of the data plane network is made up of interconnected forwarding elements (FEs). The topology of the control plane network is made up interconnected control elements (CEs). This physical independence of the control plane network from the data plane network provides for a secure mechanism to communicate among the CEs in the control plane network. In addition, this physical independence provides improved reliability and improved scalability, when compared to the traditional router architecture, where control plane message are in-band with the data plane.

A multicast non-stop forwarding (NSF) router architecture enhances high availability of a multicast router in a computer network. The router architecture further preserves multicast data forwarding through a data plane during NSF recovery of one or more failures in a control plane of the router. Various multicast components of the router cooperate to provide a checkpointing and recovery technique of the multicast NSF architecture that enables efficient restart and recovery of the control plane failures without loss of data connectivity.

Software architecture for developing distributed fault-tolerant systems independent of the underlying hardware architecture and operating system. Systems built using architecture components are scalable and allow a set of computer applications to operate in fault-tolerant/high-availability mode, distributed processing mode, or many possible combinations of distributed and fault-tolerant modes in the same system without any modification to the architecture components. The software architecture defines system components that are modular and address problems in present systems. The architecture uses a System Controller, which controls system activation, initial load distribution, fault recovery, load redistribution, and system topology, and implements system maintenance procedures. An Application Distributed Fault-Tolerant/High-Availability Support Module (ADSM) enables an applications( ) to operate in various distributed fault-tolerant modes. The System Controller uses ADSM's well-defined API to control the state of the application in these modes. The Router architecture component provides transparent communication between applications during fault recovery and topology changes. An Application Load Distribution Module (ALDM) component distributes incoming external events towards the distributed application. The architecture allows for a Load Manager, which monitors load on various copies of the application and maximizes the hardware usage by providing dynamic load balancing. The architecture also allows for a Fault Manager, which performs fault detection, fault location, and fault isolation, and uses the System Controller's API to initiate fault recovery. These architecture components can be used to achieve a variety of distributed processing high-availability system configurations, which results in a reduction of cost and development time.

A cluster router architecture and methods for performing distributed routing are presented. The cluster router architecture includes off-the shelf Personal Computer (PC) hardware-based router cluster nodes interconnected in an intra-connection network in multiple dimensions. Each PC-based router cluster node is provided with the same routing functionality and a router-cluster-node-centric configuration enabling each router cluster node by itself or multiple router cluster nodes in the cluster router to provide routing responses for packets pending processing. Optimized packet processing in respect of specific functionality is provided via special purpose router cluster nodes not necessarily PC-based taking part as cluster nodes in the cluster router lattice. The method divides packet processing into entry packet processing and routing response processing; special processing; and exit processing. Entry packet processing and routing response processing is performed by router cluster nodes receiving packets from communication networks in which the cluster router participates. Exit packet processing is performed by router cluster nodes transmitting packets into communication networks in which the cluster router participates. Packet processing in accordance with the router-cluster-node-centric specification is interrupted on determining that special processing is required in respect of a packet, and the packet is handed over to a corresponding special purpose router cluster node. Advantages are derived from: a configurable, and scalable cluster router design providing a re-configurable high routing capacity using cost effective stock PC hardware; from the intra-connection network which provides a high degree of diversity ensuring resilience to equipment failure; from the use of a star topology with respect to management links which reduces management overheads in the intra-connection network; and from the ability to forward packets to designated special purpose router cluster nodes optimized to provide specific packet processing functionality.

A method for providing enhanced service in an IP-based core network having a collapsed wireless system architecture comprises using a modified proxy-call session control function in a broadband wireless router to monitor the IP-based core network and, based on the amount of available resources, either accepting a call or rejecting the call into the network. Additionally, depending on an amount of available resources in the IP-based core network a quality of a call-in-progress or a user application may be adjusted.

A distributed multilayered network routing architecture comprises multiple layers including a controller layer comprising a controller, a control plane layer comprising one or more control plane subsystems, and a data plane layer comprising one or more data plane subsystems. A controller may be coupled to one or more control plane subsystems. A control plane subsystem may in turn be coupled to one or more data plane subsystems, which may include one or more software data plane subsystems and/or hardware data plane subsystems. In certain embodiments, the locations of the various subsystems of a distributed router can be distributed among various devices in the network.

Layout-aware modular decoupled crossbar and router for on-chip interconnects and associated micro-architectures and methods of operation. A crossbar and router architecture called MoDe-X (Modular Decoupled Crossbar) is disclosed that supports 5-port routing for use in 2D mesh interconnects and is implemented through use of decoupled row and column sub-crossbar modules in combination with feeder wiring and control logic that enables routing between ports on the row and column sub-crossbar modules. The corresponding MoDe-X router supports 5-port routing between various router input and output port combinations while reducing both router area and power consumption when compared with a conventional 5×5 crossbar design and implementation. The MoDe-X micro-architecture can be configured to support both single and dual local port injection configurations.

An aggregation router architecture comprises a plurality of line cards coupled to at least one performance routing engine (PRE) via an interconnect system. The line cards include input cards having input ports coupled to subscribers and at least one trunk card configured to aggregate packets received from the subscriber inputs over at least one output port. The PRE performs packet forwarding and routing operations, along with quality of service functions for the packets received from each input line card over the interconnect system. The interconnect system comprises a plurality of high-speed unidirectional (i.e., point-to-point) links coupling the PRE to each line card. The point-to-point links couple the line cards to a novel logic circuit of the PRE that is configured to interface the line cards to a packet buffer and a forwarding engine of the PRE.

A router comprising a plurality of elements, each having an element identifier, subdivided into a plurality of groups of at least one element. Each group has a common identifier and each member within each group shares redundant capabilities. Each element is capable of communicating with another element by addressing information to the common identifier instead of the element identifier. Optionally, one element can be a member of more than one group. Another option suggests that all elements within a group share essential information associated with a service provided by the group. Another option is implemented through one element of the router identifying a primary element for a group, wherein the primary element serves requests addressed the corresponding common identifier. Yet another option suggests that one element is identified through configuration of the router as a primary element in its group to serve requests addressed to the common identifier.

A router for interconnecting N interfacing peripheral devices. The router comprises a switch fabric and routing nodes coupled to the switch fabric. Each routing node comprises: i) a plurality of physical medium device (PMD) modules for transmitting data packets to and receiving data packets from selected ones of the N interfacing peripheral devices; ii) an input-output processing (IOP) module coupled to the PMD modules and the switch fabric for routing the data packets between the PMD modules and the switch fabric and between the PMD modules; and iii) a classification module associated with the IOP module for classifying a first data packet received from the IOP module. The classification module causes the IOP module to forward the first data packet based on the classification. The router architecture incorporates streams-based billing support, firewall capabilities, and data surveillance functionality.

An apparatus for providing a distributed router architecture includes a processing element and a resource availability element. The processing element may be configured to receive indications of receipt of data associated with a service for routing to a destination address. The resource availability element may be in communication with the processing element and may be configured to monitor resource usage over a plurality of distributed resource planes. The processing element may be further configured to allocate a resource associated with routing the data based on the monitored resource usage.

A method and a related router comprising a network interface, a logical addressing module and a forwarding element card. The logical addressing module is capable of maintaining at least one local table associating at least one card of the router with at least a portion of at least one service provided by the router. The forwarding element card is capable of receiving a packet stream on the network interface, detecting that the packet stream requires further treatment from a further card of the router and, upon detection, consulting the local table to find an identifier, to which the further card is linked, based on information found in the packet stream before forwarding the packet stream toward the further card.

A parallel router comprising: 1) a plurality of routing nodes, each of the plurality of routing nodes capable of receiving message packets from and transmitting message packets to external devices, wherein each of the routing nodes maintains a routing table suitable for routing message packets from transmitting ones of the plurality of routing nodes to receiving ones of the plurality of routing nodes; and 2) a switch fabric capable of transmitting the messages packets between the transmitting nodes and the receiving nodes, wherein a designated one of the plurality of routing nodes is operable to receive from non-designated ones of the plurality of routing nodes link state advertisement (LSA) message packets containing link state information, wherein the designated routing node aggregates the LSA message packets to thereby form a link-state database.

The invention relates an IPSec VPN (Internet Protocol Security Virtual Private Network) realizing system and method based on a NetFPGA (Net Field Programmable Gate Array), wherein a control layer of a router is additively provided with an IKE (Internet Key Exchange) module, a security relation database mapping module and a security policy database, and a key management module is used for dynamically managing the key, the security relation and the security policy; and a forward layer is additionally provided with two independently designed IPSec input and output process modules in the originalNetFPGA standard router architecture by sufficiently utilizing the modularization reusable idea of a NetPGA development board. The scheme of the invention can realize the route forward function of the data flow in a hardware manner, and can also realize the great mass of calculation functions required by the IPSecVPN in a hardware manner, such as safe detaching/packing load and completeness authentication; in addition, the invention can effectively make a compromise on the data flow forward performance and the IPSec protocol processing performance.

The invention belongs to the technical field of RFID, and in particular relates to an RFID router architecture system. It includes the middleware client layer that provides the RFID intermediate call interface and the remote login function of the RFID router; the middleware router layer responsible for providing the core middleware function, routing function and security configuration function of the RFID router; including the RFID middleware control The device layer of the reader, the computer participating in the networking and the router; the middleware client layer, the middleware router layer and the device layer are connected in sequence. The invention effectively solves the problem of insufficient combination of the RFID middleware and the RFID network, and provides technical support for introducing the RFID reader into the internal network of the enterprise and self-organizing and constructing the RFID network meeting the requirements of the enterprise.

Architectures, apparatus and systems employing scalable multi-layer 2D-mesh routers. A 2D router mesh comprises bi-direction pairs of linked paths coupled between pairs of IO interfaces and configured in a plurality of rows and columns forming a 2D mesh. Router nodes are located at the intersections of the rows and columns, and are configured to forward data units between IO inputs and outputs coupled to the mesh at its edges through use of shortest path routes defined by agents at the IO interfaces. Multiple instances of the 2D meshes may be employed to support bandwidth scaling of the router architecture. One implementation of a multi-layer 2D mesh is built using a standard tile that is tessellated to form a 2D array of standard tiles, with each 2D mesh layer offset and overlaid relative to the other 2D mesh layers. IO interfaces are then coupled to the multi-layer 2D mesh via muxes/demuxes and/or crossbar interconnects.

A router and a router architecture comprising at least one network interface, a plurality of processing elements, at least one switching element and a plurality of forwarding elements. Each of the plurality of processing elements comprises at least one processing unit, wherein each processing unit is capable of processing network traffic to provide at least a portion of a network service. The switching element is capable of acting as a proxy of the plurality of processing elements while each of the plurality of forwarding elements is capable of receiving network traffic on the at least one network interface of the router and delegating processing of network traffic toward at least one of the plurality of processing elements through the at least one switching element.