A session border controller has a processor operable to receive a message from a connected peer node. The processor inputs the message to a Message Manipulation Function, MMF, which identifies the message as a SIP message, and in response obtains external state data associated with the message from a source independent from the message. The external state data is provided to the MMF. The SIP message is modified using the MMF according to one or more conditions or rules associated with the received external state data; and the modified message is output.

A front-end computing system provides cross machine message forwarding through a kernel mode component. The message is received in a kernel mode queue of the front-end computing system. The message includes one or more headers and an entity body including one or more data blocks. A user mode router in the front-end computing system designates a computing system to process the message based at least in part on the one or more headers. The one or more data blocks are passed through the kernel mode queue in the front-end computing system to the designated computing system without passing the one or more data blocks to the user mode router in the front-end computing system.

This disclosure relates to techniques for supporting multiple Quality of Service flows for a service data flow in a wireless communication system. The service data flow may include multiple categories of data with different Quality of Service parameters. Separate Quality of Service flows may be established for each of the categories of data with different Quality of Service parameters. A cellular network and a wireless device communicating data for the service data flow may apply packet detection rules or packet filters to determine on which Quality of Service Flow to communicate data packets of the service data flow, and may communicate the data packets accordingly.

A network switch is disclosed. The network switch includes an input port and an output port. The network switch further includes a rule logic and a memory for storing a configurable counter. The rule logic is configured to inspect a packet received via the input port and attempt to find a rule for the packet and if the rule is found, to reset the counter and process the packet according to a preconfigured follow up action associated with the rule and if the rule is not found, to route the packet according to a default rule. The rule logic is configured to identify the packet for a follow up action based at least on a subset of content of the packet including a header and a payload of the packet. The counter may hold a time value or the number of packets from a same source to a same destination, a number of bytes received from the same source to a same destination, or a user configurable parameter to control the rule validity period.

A wireless communication system (100) estimates a carrier frequency offset between wireless devices (101, 102) by configuring the devices through exchanging packet configuration packets (121, 125) to specify a carrier frequency offset fingerprint (CFOF) sequence in a measurement packet (133, 136) which is transmitted between the wireless devices, where the CFOF sequence in the measurement packet includes a prefix component (31), one or more signature segments (32), and a suffix component (33) for performing CFO measurements at the wireless devices which each process IQ samples corresponding to the signature segments in the received measurement packet by correlating the IQ samples against a reference vector to generate, for each of the one or more signature segments, a carrier frequency offset estimate between the first and second wireless devices.

Systems and methods for indicating and determining channel structure information in a wireless communication network are disclosed herein. In one embodiment, a method performed by a first node is disclosed. The method comprises: receiving a wireless signal from a second node; obtaining channel structure information indicated by the wireless signal; determining a first waveform parameter set configured for the channel structure information indicated by the wireless signal; and determining transmission attributes of a transmission link between the first node and the second node in a predetermined time duration with respect to the first waveform parameter set based on the channel structure information.

Systems and methods for indicating and determining channel structure information in a wireless communication network are disclosed herein. In one embodiment, a method performed by a first node is disclosed. The method comprises: receiving a wireless signal from a second node; obtaining channel structure information indicated by the wireless signal; determining a first waveform parameter set configured for the channel structure information indicated by the wireless signal; and determining transmission attributes of a transmission link between the first node and the second node in a predetermined time duration with respect to the first waveform parameter set based on the channel structure information.

A communication apparatus for selecting a plurality of messages each including destination information indicating a common transmission destination from among a plurality of messages each including destination information indicating a transmission destination, a first generation unit configured to generate a plurality of transmission packets corresponding to the messages selected, in a batch, and a second generation unit configured to generate a transmission packet corresponding to a message not selected among the plurality of messages.

An example operation may include one or more of retrieving decentralized identifiers (DIDs) of a plurality of blockchain peers included within a blockchain network, generating a blockchain declarative descriptor (BDD) which uniquely identifies the blockchain network, where the BDD comprises a machine-readable data file with a first field includes the retrieved DIDs of the blockchain network, a second field including signature data of the plurality of blockchain peers, and a third field including metadata, and transmitting the generated BDD to a blockchain network registry.

A mobile edge computing (MEC) service area can utilized packet header source and/or destination internet protocol data and session initiation protocol source and/or destination internet protocol data to map internet protocol addresses associated with mobile devices. The MEC can comprise a translation component that translates service provider internet protocol addresses such that they are perceived as enterprise premises internet protocol addresses. Conversely, the translation component can translate enterprise premises internet protocol addresses such that they are perceived as service provider internet protocol addresses.