The present invention proposes a new method for solving the problem of fault tolerance. This new approach obtains all secondary routes assigned to each possible connection (user). The secondary routes replace the main routes when these are affected by at least one fault, which keeps the users connected as long as, for each connection, there is at least one route with operative links for reaching the destination nodes thereof. This new approach solves the general case of an arbitrary set of simultaneous link failures. The method also assesses the number of wavelengths for each link of the network, so that the probability of any connection request from a determined user c being blocked is less than a predefined threshold β.sub.c, despite the possible occurrence of the fault scenario.

The disclosure relates to a message distribution system configured to provide traffic messages received by at least one base station of a telecommunications network to at least one traffic control system capable of controlling traffic infrastructure. The message distribution system comprises a detection module and a routing module. The detection module is configured to detect traffic messages from user devices in a radio coverage area of the at least one base station. The routing module is configured to access association information associating at least one routing address of the at least one traffic control system with the radio coverage area of the at least one base station and to route the detected traffic messages to the at least one routing address associated with the radio coverage area of the at least one base station receiving the traffic messages from the user devices.

A method for transmitting a broadcast signal, includes processing one or more Internet Protocol (IP) packets into link layer packets, the one or more IP packets carrying components of one or more services and service signaling information for signaling the components of one or more services; and processing the link layer packets to output the broadcast signal includes PLPs, wherein a PLP of the PLPs includes a service list table, the service list table including a service identifier identifying a service, capabilities information representing required capabilities for decoding content for the service, protocol information representing a type of protocol used to deliver the service signaling information, the type of protocol representing either ROUTE or MMTP and an IP address for an IP packet carrying the service signaling information for the service.

A Service Routing Agent and methods are disclosed that classify and route data service requests. One embodiment includes a control circuit and at least one orchestrator, processor, and service handler circuit. The control circuit performs a process to: receive a configuration of at least one service handler circuit, initialize a list of service handler circuits and associated applications, program the at least one processor to listen for data service requests associated with the application, receive a data service request, and determine whether a service handler circuit associated with the application has been activated; when the service handler circuit has been activated, forwards the data service request to the service handler circuit, and when the service handler circuit has not been activated, request that the service handler circuit be activated, and then forwards the data service request to the service handler circuit. The Service Routing Agent reports updated traffic statistics.

Embodiments of the present disclosure provide a method and an entity for checking port consistency of NIDD message. A first aspect of the present disclosure provides a method performed at a first entity (100), comprising: receiving (S101), from a second entity, a non-internet protocol data delivery, NIDD, message including one or more RDS port numbers; and determining (S102) whether the one or more RDS port numbers are within a configured RDS port list. According to embodiments of the present disclosure, network resources for transmitting the invalid NIDD data may be saved, and undesired actions in the communication system may be avoided.

Embodiments of the present disclosure disclose a signaling packet processing method and an entity. The method may include: obtaining, by a gateway user plane entity, processing information of a target signaling packet; and receiving, by the gateway user plane entity, the target signaling packet, and processing the target signaling packet according to the processing information. Network costs can be reduced in the embodiments of the present disclosure.

A communication apparatus is mounted on a train and forms a train communication system together with a system control apparatus that generates control frames including general and low-latency frames. The communication apparatus includes: a general transfer processing unit that stores the general frame; a low latency transfer processing unit that stores the low-latency frame, the low latency frame requiring transferring with lower latency than the general frame; a frame identification unit that identifies priority of the control frame and outputs the control frame to the general transfer processing unit or the low latency transfer processing unit based on a priority setting table indicating the priority of the control frame and set in the identification unit; an output control unit that preferentially transfers the low-latency frame over the general frame; and a control unit that modifies the priority setting table.

In one embodiment, segment routing (SR) network processing of packets is performed which includes operations signaling and processing of packets in manners providing processing and/or memory efficiencies. One embodiment includes acquiring a segment routing particular packet by a particular router in a network. Responsive to the particular router data plane ascertained during fast path processing by a fast path processing unit that the segment routing particular packet is to be Operations, Administration, and Maintenance (OAM) processed by a different processing unit in the particular router, communicating a time stamp of a current time and the segment routing particular packet including a segment routing header that includes OAM signaling from said fast path processing to the different processing unit, with fast path processing being hardware-based packet processing by the fast path processing unit. The segment routing particular packet is OAM processing by the different processing unit.

This disclosure describes techniques for applying a policy proximate to a source of data traffic in a network. The techniques include indicating to a destination edge node that a policy relevant to the data traffic has not been applied at a source edge node. The destination edge node may send the policy to the source edge node. The source edge node may apply the policy to a subsequent packet of the data traffic. Application of the policy proximate to the source of the data traffic may conserve network resources and improve performance of the network.

An Autonomous System (AS) may receive an AS route update from a remote AS at an isolated border gateway (BGW) router of an AS. The AS may analyze a data traffic routing path in the AS route update to determine whether the AS route update is a problematic update, the data traffic routing path for routing data traffic through a plurality of ASs that include the AS. In response to determining that the AS route update is a non-problematic update, the AS may implement the AS route update into the one or more operational BGW routers of the AS to route the data traffic between the plurality of ASs. In response to determining that the AS route update is a problematic update, the AS may designate the AS route update from the remote AS as unsuitable for implementation into one or more operational BGW routers of the AS.