Abstract: A radio frequency (RF) bus controller includes an interface and a processing module. The interface is coupled for communicating intra-device RF bus access requests and allocations. The processing module is coupled to receive an access request to an RF bus via the interface; determine RF bus resource availability; and when sufficient RF bus resources are available to fulfill the access request, allocate, via the interface, at least one RF bus resource in response to the access request.

Abstract: An intelligent network interface card (INIC) or communication processing device (CPD) works with a host computer for data communication. The device provides a fast-path that avoids protocol processing for most messages, greatly accelerating data transfer and offloading time-intensive processing tasks from the host CPU. The host retains a fallback processing capability for messages that do not fit fast-path criteria, with the device providing assistance such as validation even for slow-path messages, and messages being selected for either fast-path or slow-path processing. A context for a connection is defined that allows the device to move data, free of headers, directly to or from a destination or source in the host. The context can be passed back to the host for message processing by the host. The device contains specialized hardware circuits that are much faster at their specific tasks than a general purpose CPU.

Abstract: A system and method for reduced forwarding information storage includes extracting an organizationally unique identifier (OUI) and a MAC part from a MAC address, determining whether information associated with the OUI is stored in an OUI table, determining an OUI index based on the information associated with the OUI and the OUI table when the OUI is stored in the OUI table, generating the OUI index based on the information associated with the OUI when the OUI is not stored in the OUI table, forming a forwarding information table entry including information associated with the OUI index and information associated with the MAC part, and inserting the forwarding information table entry into a forwarding information table.

Abstract: Disclosed is a method and corresponding system for dynamically activating a relay in a radio access network (RAN) that includes a plurality of base stations. Each base station may radiate to define one or more respective wireless coverage areas, and each coverage area may operate on one or more carrier frequencies. The RAN may be arranged to receive, from a user equipment device (UE) that is being served by a base station of the RAN on a first carrier frequency, a report indicating threshold low wireless performance on the first carrier frequency. In response to the report indicating threshold low wireless performance, the RAN may be arranged to then activate a relay that functions to communicate with the base station over a relay backhaul interface, and communicate with the UE on a second carrier frequency that is different from the first carrier frequency.

Abstract: A first end node obtains trace information in a packet switched network. The first end node sends a request message for setting up a test call towards a second end node. The request message includes a first request for collecting trace information. The second end node sends a first response message, to the first end node, that includes a trace request and trace information. The first response message is routed between the second and first end nodes via at least a first intermediate node that adds additional trace information relating to the first intermediate node to the trace information of the first response message. The first end node receives the first response message, which includes the additional trace information added by the first intermediate node.

Abstract: Some demonstrative embodiments include apparatuses, systems and/or methods of wireless backhaul and access communication via a common antenna array. For example, an apparatus may include a wireless communication unit to control an antenna array to form one or more first beams for communicating over one or more access links and to form one or more second beams for communicating over one or more backhaul links, the access links including wireless communication links between a wireless communication node and one or more mobile devices, and the backhaul links including wireless communication links between the wireless node and one or more other wireless communication nodes.

Abstract: A wireless transmit/receive unit (WTRU) includes circuitry configured to receive first information from a wireless network, the first information indicating a first pattern of time intervals in which the WTRU is to monitor a plurality of control channels; not monitor the plurality of control channels in time intervals outside the first pattern of time intervals; and receive second information from the wireless network, the second information indicating a second pattern of time intervals in which the WTRU is to transmit control information on a control channel.

Abstract: Systems for channel selection in power line communications (PLC) are described. In some embodiments, a PLC device may include a processor and a memory. The memory stores instructions executable by the processor to cause the PLC device perform operations. One or more time slots in each of a plurality of frequency bands are sequentially scanned. A packet transmitted by a second PLC device to the PLC device over one of the plurality of frequency bands is detected. Additional packets received from the second PLC device are synchronized across the plurality of frequency bands based, at least in part, upon the detected packet. The additional packets are organized in a plurality of frames. Each of the plurality of frames having been transmitted by the second PLC device to the PLC device over a respective one of the plurality of frequency bands. Each frame has a plurality of time slots, and each time slot has a pair of beacon and bandscan packets.

Abstract: A communication device configured to transmit and receive simultaneously, over the same wire, unidirectional high definition video and bidirectional data. The communication device includes a hybrid circuit coupled to a cable made of wires, and a transceiver. The transceiver is configured to transmit, over one of the cable's wires, Transition Minimized Differential Signaling (TMDS) data and source-to-sink direction of bidirectional data. The transceiver is further configured to receive the opposite direction of the bidirectional data over the same wire and simultaneously with the transmitting.

Abstract: On the mobile communication terminal 100 side, when the VOIP communication application stored in the storage unit 104 is activated in accordance with an instruction from the user (step S101), the application activation judging unit 107a judges that the VOIP communication application has been activated. Upon the judgment, the control unit 107 selects a cycle (for example, 1.152 seconds: code F10) that is shorter than 5.152 seconds, generates an EISP signal based on the selection, and transmits the generated EISP signal to the base station 200 via the transmission unit 102 (step S102). After this, upon receiving an ACK signal, the control unit 107 starts to activate the reception unit 103 at the cycle of 1.152 seconds to receive the report signal at the cycle of 1.152 seconds (step S105).

Abstract: The present invention relates to a method and apparatus for requesting scheduling of resources to be used for uplink communication of data in a communications system. If the repeated transmission by a user equipment of scheduling requests on an uplink control channel is determined to be unsuccessful, a random access transmission on a random access channel is initiated as a fallback procedure.

Abstract: A core network access packet data node and a core network access edge node are described herein. The core network access packet data node and/or the core network access edge node is/are adapted to hold or receive access priority related information comprising a subscriber related access allocation priority parameter relating to a subscriber requesting a network resource. Further, the core network access packet data node and/or the core network access edge node is/are adapted to have a preliminary access decision unit being provided for deciding if a network resource request is to be handled. Moreover, the core network access packet data node and/or the core network access edge node is/are adapted to have a final decision unit being provided for making a final decision relating to grant/rejection of a request to be handled, i.e. given preliminary access.

Abstract: A method for reporting and obtaining channel state information, an eNodeB, and a user equipment are disclosed. The method for reporting channel state information includes: determining a reported content in channel state information (CSI) of downlink component carriers according to priorities of contents-in-CSI, where the CSI of the downlink component carriers includes the reported content and a content that is not to be reported; and reporting the reported content to an eNodeB on a physical uplink control channel (PUCCH). By determining a reported content in CSI according to a priority, the shortage of a CSI reporting resource may be relieved.

Abstract: A method for optimizing network performances, wherein the network includes one or more network nodes (1), performance parameters of the network nodes (1) being controlled by element of dedicated optimization modules (3), wherein each optimization module (3) monitors at least one performance parameter of the network node (1) to which the optimization module (3) is associated and generates a change request for the current value of the performance parameter on the basis of preset rules, is characterized in that the change requests generated by different optimization modules (3) of the network node (1) are forwarded to a shared controlling element (2), wherein the shared controlling element (2) enforces a coordination of the received change requests on the basis of a configurable algorithm. Furthermore, a corresponding system is disclosed.

Abstract: Disclosed herein are apparatus, method, and computer program whereby a mobile station receives an indication from a base station in a physical layer field and interprets the indication for use in at least a power management function.

Abstract: A method and an arrangement in a first radio network node for determining a channel quality offset for a radio channel for sending data from the first radio network node to a user equipment are provided. The first radio network node receives from the user equipment channel quality information for the radio channel. The first radio network node estimates resource utilization and signal-to-noise-ratio for the user equipment. The first radio network node determines the channel quality offset based on the received channel quality information, the estimated resource utilization and the estimated signal-to-noise-ratio.

Abstract: A method (200) for data transmission from a sender (110) to a receiver (120), wherein the data transmission is performed in predefined time intervals by associated transmission processes. The sender (110) is adapted to perform a subsequent transmission for the associated process in a time interval after one round trip time (502). Specific transmissions are performed among the transmissions, wherein the specific transmissions are limited to a subset of the time intervals, the subset being smaller than the number of all time intervals in a round trip time (502). The method (200) comprises the steps of determining (230) a maximum number of specific transmissions within a round trip time (502), specifying (240) a number of associated processes for the specific transmissions, wherein the specified number is the maximum number, and associating (250) the processes for the specific transmissions with the specific transmissions.

Abstract: Methods and apparatus for load balancing across member ports for traffic egressing out of a port channel are provided herein. An example method according to one implementation may include: assigning a quantized value based on current load to each of the network ports in the port channel; receiving a data packet addressed to egress through the port channel; identifying a traffic flow with which the received data packet is associated; determining whether the identified traffic flow is a new traffic flow; and selecting one of the network ports in the port channel as an egress port. Selection of the egress port may be weighted according to the quantized value of each of the network ports in the port channel.

Abstract: A method for activating a node in a Wireless Sensor Network includes detecting and amplifying pulse signals from a base station; determining whether pulses in the amplified pulse signal are valid; and counting valid pulses in three time periods. A target identifier is calculated using a predetermined formula and numbers of the valid pulses counted. Whether the target identifier matches an identifier of the communication system is determined. The communication system when the target identifier matches the identifier of the communication system is activated. The node is also provided.

Abstract: In a wireless communication device for performing plural wireless communications with different standards using the same frequency band, degradation of communication quality and communication speed due to communication interference is prevented, while drop in throughput and occurrence of frame loss are prevented. A first wireless communication section first performs wireless communication using a first frequency band and a second wireless communication section performs second wireless communication using a second frequency band with which at least a part of the first frequency band overlaps.