Abstract: A communication system includes a source PNNI node. The system includes a destination PNNI node. The system includes a network having logical group nodes representing peer groups through which the source node and the destination node communicate by establishing an SPVC using a DTL which identifies the group nodes representing the peer groups with only a partial node ID. A method for communicating includes the steps of forming a DTL which identifies logical group nodes representing peer groups with only a partial node ID. There is the step of establishing an SPVC using the DTL through which a source PNNI node and a destination PNNI node of a network communicate.

Abstract: An apparatus for providing passive automated provisioning may include an address monitoring element and an address provisioning element in communication with the address monitoring element. The address monitoring element may be configured to issue a first query for a device assigned to a monitoring address. The address provisioning element may be configured to assume or maintain a passive address, different than the monitoring address, if another device responds to the first query and to invoke an address replacement routine if no other device responds to the first query.

Abstract: The subject matter described herein includes methods, systems, and computer program products for source-aware IP routing at a media gateway. According to one aspect, a method for source-aware IP routing at a media gateway is provided. The method includes providing a packet including a layer 3 source address and a layer 3 destination address at a media gateway having a source-aware routing table. Using the destination address included in the packet, at least one entry corresponding to the destination address is located in the source-aware routing table, where the located entry contains at least a portion of a source IP address, at least a portion of a destination IP address and routing information including an interface identifier and a next hop identifier. From among the at least one located entry corresponding to the destination IP address information, at least one entry corresponding to the source IP address included in the packet is located.

Abstract: A network terminal device is configured to include a plurality of network applications that generate process instructions to cause devices on a network to execute processes, a storage unit that stores common network configuration information of the plurality of network applications, and a network terminal device where each of the plurality of network applications is capable of reading out the common network configuration information from the storage unit and reflecting the same in its own network configuration. Each application may transmit the process instructions to the device on the network based on the network configuration.

Abstract: A method, system, network and gateway of deciding a policy for controlling communications in a communication system are disclosed. The method comprises determining the type of an access network associated with communications via a gateway. In a further step, a policy to apply to communications via the gateway is decided based on information regarding the type of the access network.

Abstract: A data transmission method and system by which an arrival delay can be controlled are provided. A node (i) calculates a cumulative delay CUM_DLY(i) of a received packet cumulated up to the current hop, by using an arrival delay of the packet and a cumulative delay CUM_DLY(i?1) cumulated up to the previous hop, and compares the cumulative delay CUM_DLY(i) with a target cumulative delay TAR_CUM_DLY(i), thereby controlling a transmission profile for the packet so that an expected cumulative delay at the next node becomes closer to a target value. The node (i) writes the cumulative delay CUM_DLY(i) in a header of the packet and transmits the packet to the next node using the set transmission profile. Similar transmission profile control is carried out at each transit node in a multi-hop system, whereby the cumulative delay in the entire system can be controlled within a desired range.

Abstract: A method of controlling data transmission mode in an orthogonal frequency division multiple access (OFDMA) wireless relay system and an apparatus using the method are provided. The method of controlling data transmission mode includes: dividing all frequency bands of an OFDM signal into a frequency band group including at least one subcarrier band; estimating a plurality of channels of wireless links which respectively link a base station (BS), at least one relay station (RS), and a mobile station (MS) with respect to the at least one subcarrier band; selecting any one of a plurality of data transmission modes based on a feature of the estimated plurality of channels of wireless links with respect to the frequency band group; and applying the selected data transmission mode to all of the at least one subcarrier bands in the frequency band group to transmit data.

Abstract: A method for IP Security within Multi-Topology Routing is disclosed. Disclosed methods may also include IKE extensions. A route eligible for IPSec protection is injected into a topology routing table. Network traffic can then be protected in accordance with a security session, such as an IPSec session, between a first network node and a second network node and forwarded through a selected topology to take advantage of the service-differentiation capabilities of MTR.

Abstract: Method, systems, and computer program products for voice over IP (VoIP) traffic engineering and path resilience using media gateway and associated next-hop routers are provided. In one example, a media gateway includes multiple media processing hosts and a multiple network interfaces separate from the media processing hosts. At least one of the media processing hosts is reachable via at least two of the network interfaces. Next-hop routers associated with the network interfaces advertise reachability information regarding the media processing hosts to routers in the network. The next-hop routers also participate in network routing protocols to form multiple paths between the media gateway and a remote media gateway. Costs may be assigned to associations between the media processing hosts and the next-hop routers for traffic engineering purposes.

Abstract: A system for dynamic tagging of network data based on service level objectives comprises one or more processors and memory coupled to the processors. The memory comprises program instructions executable by the processors to identify a service level objective associated with a particular task that comprises a transmission of data packets over a network on behalf of an application, where the network includes one or more devices (such as routers, switches, etc.) configured to provide different levels of service to data packets based at least in part on service level indicators included within the packets. The instructions are executable to dynamically generate service level indicators corresponding to the identified service level objectives for inclusion in the data packets of the task, and to transmit the packets including the service level indicators into the network.

Abstract: A technique is disclosed that enables a set of information to be represented by data packets, where those data packets can then be distributed as needed throughout the telecommunications system that uses the data. The data packet of the illustrative embodiment is an autonomous encapsulation of data, a subsection of a data model at a certain time in relation to other data in the system at another time. The data packet is identified at a particular time and value with a globally unique identifier. Relationships of the data packet to other data packets are made known by using references to the other packets. As a result, referenced data packets are retrieved throughout the system based on their relationships to each other. Whenever a data packet is transmitted or received, each node involved in the transmission applies rules that determine where the data has to be transmitted to and what to do with the data when received.

Abstract: Methods, apparatus, and products are disclosed for remotely booting computing nodes in a switching domain, the switching domain capable of connecting to other switching domains through a network switch, that include: receiving, in the switch, a wakeup request packet that requests activation of one or more computing nodes in the switching domain, the wakeup request packet having a process port value specifying physical ports on the switch to which the one or more computing nodes are physically connected; identifying, by the switch, a network address for each computing node in dependence upon the physical port on the switch to which each computing node to be activated is physically connected; generating, by the switch, a wakeup packet for each computing node in dependence upon the identified network address for that computing node; and transmitting, by the switch to each computing node to be activated, the wakeup packet for that computing node.

Abstract: An incoming data packet is received, and a rate of change of residual capacity of a portable power supply is determined. From the determined rate of change it is decided to enqueue or drop the incoming data packet. If the decision is to enqueue, the packet is transmitted. If the decision is drop, the packet is deleted without transmitting. Additional factors may be considered in the decision, such as total energy capacity, residual energy capacity, and first and second derivatives of the residual energy capacity. Real time traffic may be treated differently than non real time traffic, and video enhancement layer packets can be weighted to drop more frequently than video base layer packets for the same flow. If used in the network, congestion probe packets are dropped at a rate matched to the rate at which data packets are dropped to give other nodes an accurate view of link quality.

Abstract: An apparatus for sharing user-defined media content with a peer. The apparatus comprises a repository for storing media content inputted by a user of the apparatus and a wireless interface for establishing a wireless personal area network (WPAN) with a first communication entity of the peer in a proximity to said apparatus. The WPAN allows the peer to access the media content using the first communication entity, thereby allows the user to share said media content with the peer.

Abstract: On the transmission side, the RLC PDUs divided from the RLC SDU are transmitted after retransmission identification information is attached thereto. On the reception side, the retransmission identification information attached to each received RLC PDU is referred to, and only the RLC PDUs having an identical retransmission identification information to a set assumed value are stored in a buffer memory, and the RLC PDUs having the identical retransmission identification information are assembled into an RLC SDU.

Abstract: The present invention relates to a system and method for extending the coverage area and communication capacity of a spread-spectrum based wireless network through the use of intelligent repeaters. The system comprises a wireless communication network augmented with low cost channel selective repeaters that is capable of repeating only desired signals, thereby suppressing undesirable interference and increasing network capacity. The repeaters can be integrated into an existing wireless network with minimal impact to the existing network layer topology or control structure.

Abstract: A communications network arrangement provides voice over IP or voice over ATM services. The network arrangement comprises a first media gateway controller controlling a first gateway and provided with a first operating protocol, a second media gateway controller controlling a second gateway and provided with a second operating protocol, and a gateway address translator incorporating proxies for the first and second gateways. The gateway address translator provides a relay function for messaging between each media gateway controller and its corresponding gateway, and a virtual bearer function for messaging between the media gateway controllers. This facilitates inter-working between products supplied by different vendors.

Abstract: DisplayPort micropackets of uncompressed visual information are adapted for communication across a network by stuffing packets with sink device identification information. For example, a packet stuffer adds selected portions of sink device EDID information to DisplayPort packets, such as EDID bytes 8 through 15, to a predetermined portion of the DisplayPort packets, such as between symbols FS and FE. Adding sink device identification information to each DisplayPort packet supports routing or switching of the packets to the identified sink device.

Abstract: One feature provides a method for encoding geolocation information into a next-generation internet protocol (IP) address, such as IPv6, to facilitate distribution of geolocation information among networked devices. A request for an IP address assignment is received from a network device. The geographical location for the network device is obtained. An IP address is assigned or generated that includes the geographical location. The assigned IP address is then provided to the network device. By encoding the geolocation information of a first network device into the IP address assigned to the first network device, other network devices are able to readily obtain the geographical location of the first network device. This method propagates geolocation information for network devices as part of the IP address, thus avoiding the need for separate geolocation distribution messaging. As the network device moves, its IP address is changed to update its geographical location information.

Abstract: Methods and apparatus operating in a stream processing network perform load shedding and dynamic resource allocation so as to meet a pre-determined utility criterion. Load shedding is envisioned as an admission control problem encompassing source nodes admitting workflows into the stream processing network. A primal-dual approach is used to decompose the admission control and resource allocation problems. The admission control operates as a push-and-pull process with sources pushing workflows into the stream processing network and sinks pulling processed workflows from the network. A virtual queue is maintained at each node to account for both queue backlogs and credits from sinks. Nodes of the stream processing network maintain shadow prices for each of the workflows and share congestion information with neighbor nodes.