Systems and methods for dynamic communication routing based on consistency weighting and routing rules are disclosed. A computing device can receive a communication including content data. The communication can be stored in a queue position of a primary queue. For example, the primary queue can include a plurality of queue positions for storing communications. The communication can be retrieved from the queue position of the primary queue and analyzed. In some instances, analyzing can include parsing the content data for a keyword. A keyword can correspond to a secondary queue. When the keyword is identified in the communication, the communication can be stored in the secondary queue that corresponds to the keyword. A terminal device associated with the secondary queue can be identified. A retrieval request to access the communication from the secondary queue can be received, and the communication can be routed to the terminal device.

Systems and methods for dynamic communication routing based on consistency weighting and routing rules are disclosed. A computing device can receive a communication including content data. The communication can be stored in a queue position of a primary queue. For example, the primary queue can include a plurality of queue positions for storing communications. The communication can be retrieved from the queue position of the primary queue and analyzed. In some instances, analyzing can include parsing the content data for a keyword. A keyword can correspond to a secondary queue. When the keyword is identified in the communication, the communication can be stored in the secondary queue that corresponds to the keyword. A terminal device associated with the secondary queue can be identified. A retrieval request to access the communication from the secondary queue can be received, and the communication can be routed to the terminal device.

A method for predicting fraudulent call activity is provided. The method includes receiving one or more datasets indicating call activity corresponding to a phone number, and analyzing the one or more datasets to identify unusual call activity. The method further includes generating a fraud prediction, based at least in part on the identified unusual call activity, that the phone number will be used for fraud.

A method for predicting fraudulent call activity is provided. The method includes receiving one or more datasets indicating call activity corresponding to a phone number, and analyzing the one or more datasets to identify unusual call activity. The method further includes generating a fraud prediction, based at least in part on the identified unusual call activity, that the phone number will be used for fraud.

Provided are a path, a path information processing method and device, a storage medium, and an electronic device. The path processing method may be performed by an I-SMF and include: receiving a first message sent by an anchor-session management function (A-SMF), wherein the first message comprises context information associated with a User Equipment (UE); determining, according to the context information, a mode corresponding to a data path established by the I-SMF, wherein the mode is indicative of whether the data path supports a Protocol Data Unit (PDU) session with multi-homing function; and determining a node type of a node according to the mode, wherein the node type comprises an uplink classifier (UL-CL) or a branching point (BP).

Provided are a path, a path information processing method and device, a storage medium, and an electronic device. The path processing method may be performed by an I-SMF and include: receiving a first message sent by an anchor-session management function (A-SMF), wherein the first message comprises context information associated with a User Equipment (UE); determining, according to the context information, a mode corresponding to a data path established by the I-SMF, wherein the mode is indicative of whether the data path supports a Protocol Data Unit (PDU) session with multi-homing function; and determining a node type of a node according to the mode, wherein the node type comprises an uplink classifier (UL-CL) or a branching point (BP).

A method, a device, and a non-transitory storage medium are described in which a remote probing for failover service is provided. The remote probing for failover service includes receiving, by a network device at a standby location associated with a geographic redundancy, failover traffic, which originates at a primary location of a network. The network device routes the failover traffic back to a corresponding network device at the primary location. The network device at the primary location may provide the failover traffic to a network performance analyzer device at the primary location.

Provided is a path control method of controlling a path of communication in a network including a high priority device dealing with high priority traffic, a high priority control device communicating with the high priority device through a plurality of signal transfer devices transferring signals by periodically repeating a high priority signal transmissible period in which high priority traffic is transmissible and a low priority signal transmissible period in which low priority traffic is transmissible, a low priority device dealing with the low priority traffic, and a low priority control device communicating with the low priority device through the plurality of signal transfer devices, the path control method including calculating a low priority signal transmissible period in each of paths between the low priority device and the low priority control device, and performing setting for switching the path between the low priority device and the low priority control device so that the low priority traffic is transmitted in any one of the calculated low priority signal transmissible periods.

Provided is a path control method of controlling a path of communication in a network including a high priority device dealing with high priority traffic, a high priority control device communicating with the high priority device through a plurality of signal transfer devices transferring signals by periodically repeating a high priority signal transmissible period in which high priority traffic is transmissible and a low priority signal transmissible period in which low priority traffic is transmissible, a low priority device dealing with the low priority traffic, and a low priority control device communicating with the low priority device through the plurality of signal transfer devices, the path control method including calculating a low priority signal transmissible period in each of paths between the low priority device and the low priority control device, and performing setting for switching the path between the low priority device and the low priority control device so that the low priority traffic is transmitted in any one of the calculated low priority signal transmissible periods.

A data transmission method and a first electronic device are provided. The data transmission method includes: sending a first request to a second electronic device in a case that a first electronic device accesses a network hotspot of the second electronic device; receiving a first response of the network hotspot that is fed back by the second electronic device in response to the first request. The first response includes the hotspot information. The data transmission method further includes when the hotspot information does not include a Domain Name Service (DNS) parameter of the network hotspot, configuring a data network route to transmit first data, and configuring a target policy route to transmit second data. The second data is data transmitted between the first electronic device and the network hotspot.