A computing device (such as a computer gaming console) uses only a single radio to concurrently communicate with a wireless network access point and wireless client devices such as game controllers or peripherals. To establish and maintain both a high-throughput link with the access point, and a low-latency link with the client device(s), the single Wi-Fi radio of the computing device is configured to periodically switch between a channel used for the high-throughput link and a different channel that is used for the low-latency link—thus implementing a combination of frequency division multiplexing (FDM) and time division multiplexing (TDM). The console may use aspects of the Wi-Fi protocol standard to ensure that periodically switching its single radio between the two channels is accomplished while maintaining reliable communication on both channels.

Apparatuses, methods, and systems are disclosed for data packet routing in a remote unit. An apparatus includes a memory coupled to a processor, where the processor configured to cause the apparatus to receive a data packet to be transmitted and determine a matching UE route selection policy (“URSP”) rule for the data packet. The processor is configured to determine packet routing information for the data packet if the matching URSP rule does not indicate that direct offload of the data packet is preferred and determine whether the packet routing information matches a first network connection. Upon determining that the packet routing information matches the first network connection, the processor is configured to cause the apparatus to transmit the data packet to a mobile communication network over the first network connection.

A system, server, and method of DTMF detection in a VoIP network.

A communication method, a communication apparatus, a communication device, and a storage medium are provided. The communication method includes: receiving a forwarding initiation message sent by a second communication node, where the forwarding initiation message carries a new forwarding address; and initiating a new forwarding process according to the new forwarding address in the forwarding initiation message.

A base station (20A) that, in a base station system (1) including a first base station (10) and at least two second base stations (20A, 20B), functions as the first base station (10), includes: a MAC processing unit (103) that performs MAC layer processing and generates a first MAC frame used in common between the first base station (10) and the second base station (20A); and a communication processing unit (105A) that transmits the first MAC frame to the second base station (20A).

Concepts and technologies directed to an integrated telecommunications roadside unit for supporting vehicle-to-everything (“V2X”) communications are disclosed herein. Embodiments of an integrated telecommunications roadside unit can include a processor and a memory that store computer-executable instructions that configure a processor to perform operations. The operations can include intercepting a vehicle-to-vehicle communication that is provided from a first vehicle to a second vehicle. The vehicle-to-vehicle communication can be transmitted using a direct transmission mode. The operations can further include encapsulating the vehicle-to-vehicle communication in a user plane package. The operations can also include routing the user plane package to a destination network access node, where the destination network access node is outside of a direct communication range corresponding to the first vehicle and the second vehicle.

A central routing function (CRF) platform. The CRF platform comprises at least one processor; a non-transitory memory communicatively coupled to the at least one processor that stores a plurality of prioritized international call route lists where each prioritized international call route list associates alternative international communication service carrier routes in a prioritized order with an international telephone number; and a call process application stored in the non-transitory memory that, when executed by the processor, receives a request for a prioritized international call route list from a network element, where the request comprises an international telephone number, pads out the international telephone number received from the network element to form a 15-digit number, looks up a prioritized international route list using the 15-digit number in the non-transitory memory, and sends the prioritized international route list to the network element.

Methods and systems are provided for supporting efficient and secure “Machine-to-Machine” (M2M) communications using a module, a server, and an application. A module can communicate with the server by accessing the Internet, and the module can include a sensor and/or an actuator. The module, server, and application can utilize public key infrastructure (PKI) such as public keys and private keys. The module can internally derive pairs of private/public keys using cryptographic algorithms and a first set of parameters. A server can authenticate the submission of derived public keys and an associated module identity. The server can use a first server private key and a second set of parameters to (i) send module data to the application and (ii) receive module instructions from the application. The server can use a second server private key and the first set of parameters to communicate with the module.

The present invention provides for a modular radio frequency communications assembly including a radio frequency hub and one or more radio frequency modules. Each radio frequency module includes a power and data interface for receiving power from and exchanging data with a modular radio frequency hub and a processor and memory for providing at least one of change a communications frequency, increase communications bandwidth, or add security using the one or more antennas and the power and data interface. The radio frequency hub includes two or more communications interfaces for connecting to two or more radio frequency modules, wherein each of the communications interfaces have the same physical and electrical configuration; A shared data and power interface for sharing data and power among the two or more radio frequency modules. A bus distributes data and power among the two or more radio frequency modules. One or more antenna interfaces are located on the RF hub or the RF modules for connecting radio frequency antennas.

A network controlling entity in a heterogeneous or local area network (such as a macro eNB) selects a set of network access nodes that share a common wake-up area code WUAC. The network controlling entity selects a transmission entity such as a motile terminal/UE and directs it to wirelessly transmit a signal on a given radio resource. The network controlling entity also informs each network access node within the set of the given radio resource on which they should listen for the signal. In various embodiments the network access nodes within the set can choose whether or not to listen for the signal and thus choose whether they will wakeup, or they can reply to the signal with a request for wakeup confirmation. In this manner WUAC-specific sets of small cells can be awakened only when needed for traffic offloading and thereby saving energy.