A method of detecting Quick User Datagram Protocol Internet Connections, QUIC, traffic in a telecommunication network between a User Equipment, UE, and a Content Provider, CP, wherein said UE has an established application session with said CP, for a particular application, using QUIC as transport protocol, wherein said method comprises the steps of receiving, by a User Plane Function, UPF, comprised by said telecommunication network, from said CP, a list of connection identifiers that identify said established application session between said UE and said CP, receiving, by said UPF, a QUIC packet comprising a connection identifier, detecting, by said UPF, said QUIC traffic by determining that said connection identifier of said received QUIC packet is comprised by said list of connection identifiers.

A method and apparatus for monitoring network performance in near real-time by making measurements on packets received at an intermediate node in a wireless communication network. The solution is useful for any packetized communication network that connects a client and application server, and particularly for any application running over TCP/IP protocol. A method is disclosed for measuring end-to-end qualities of a packet-based communication session between a data sender (DS) and a data receiver (DR) at an intermediate node. The measured end-to-end communication qualities may include latency and packet delay variation.

A method and apparatus for monitoring network performance in near real-time by making measurements on packets received at an intermediate node in a wireless communication network. The solution is useful for any packetized communication network that connects a client and application server, and particularly for any application running over TCP/IP protocol. A method is disclosed for measuring end-to-end qualities of a packet-based communication session between a data sender (DS) and a data receiver (DR) at an intermediate node. The measured end-to-end communication qualities may include latency and packet delay variation.

Methods, systems, media devices, and non-transitory, machine-readable media to facilitate asynchronous wireless media transfer are disclosed. A request for video service from a content provider system via a wireless network may be received. A media device may be configured to provide an asynchronous session for subsequent video content transfer. The configuring may utilize a network layer and a transport layer without utilizing a presentation layer and an application layer. Specifications of asynchronous session parameters may be created to define delivery operations with the asynchronous session. An encrypted token, corresponding to the specifications, may be created. Opening of the asynchronous session may be requested by transmitting the encrypted token to the content provider system from the transport layer. At the session layer, the asynchronous session may be started for video content delivery in accordance with the specifications of the asynchronous session parameters. Display of the video content may be caused.

Methods, systems, media devices, and non-transitory, machine-readable media to facilitate asynchronous wireless media transfer are disclosed. A request for video service from a content provider system via a wireless network may be received. A media device may be configured to provide an asynchronous session for subsequent video content transfer. The configuring may utilize a network layer and a transport layer without utilizing a presentation layer and an application layer. Specifications of asynchronous session parameters may be created to define delivery operations with the asynchronous session. An encrypted token, corresponding to the specifications, may be created. Opening of the asynchronous session may be requested by transmitting the encrypted token to the content provider system from the transport layer. At the session layer, the asynchronous session may be started for video content delivery in accordance with the specifications of the asynchronous session parameters. Display of the video content may be caused.

Example communications systems, methods and network devices are described. One example method includes sending a first message by a first access network device to a core network device to enable the core network device to send a second message to a second access network device, where the first message includes an identity of the second network device. The first message is used to request for X2 transport network layer (TNL) configuration information of a third network device, and the third network device is a network device that has established an X2 connection to the second network device. The first network device receives the X2 TNL configuration information of the third access network device from the second access network device. Therefore, a network device connected to a control plane of a core network can obtain TNL addresses of more network devices that are not connected to the control plane of the core network.

Example communications systems, methods and network devices are described. One example method includes sending a first message by a first access network device to a core network device to enable the core network device to send a second message to a second access network device, where the first message includes an identity of the second network device. The first message is used to request for X2 transport network layer (TNL) configuration information of a third network device, and the third network device is a network device that has established an X2 connection to the second network device. The first network device receives the X2 TNL configuration information of the third access network device from the second access network device. Therefore, a network device connected to a control plane of a core network can obtain TNL addresses of more network devices that are not connected to the control plane of the core network.

Methods and apparatus for traffic enhancement to apply to an application, to be delivered using a QUIC session, between a wireless device and a server. A request to activate a policy for the application between the wireless device and the server is received from the wireless device, the request including an application identifier and an indication to request an enhancement function. In response to the request to activate the policy, an authorization of traffic enhancement with information of a proxy node is transmitted to the wireless device to provide the enhancement function upon the network node identifying the proxy node.

A materials handling vehicle comprises a distributed processor system including a vehicle network that facilitates an exchange of information with vehicle electronic components, and a distributed multi-processor vehicle control architecture. The distributed multi-processor vehicle control architecture includes an embedded information core having a core processor communicably coupled to the vehicle network, and a tablet having a tablet processor, where the tablet is communicably couplable to, and detachable from the distributed multi-processor vehicle control architecture. When the tablet is detached from the distributed multi-processor vehicle control architecture, the core processor functions as a primary processor that communicates with vehicle electronic components by communicating therewith across the vehicle network. When the tablet is communicably attached to the distributed multi-processor vehicle control architecture, the tablet processor functions as the primary processor, and the core processor functions as a subordinate processor.

A materials handling vehicle comprises a distributed processor system including a vehicle network that facilitates an exchange of information with vehicle electronic components, and a distributed multi-processor vehicle control architecture. The distributed multi-processor vehicle control architecture includes an embedded information core having a core processor communicably coupled to the vehicle network, and a tablet having a tablet processor, where the tablet is communicably couplable to, and detachable from the distributed multi-processor vehicle control architecture. When the tablet is detached from the distributed multi-processor vehicle control architecture, the core processor functions as a primary processor that communicates with vehicle electronic components by communicating therewith across the vehicle network. When the tablet is communicably attached to the distributed multi-processor vehicle control architecture, the tablet processor functions as the primary processor, and the core processor functions as a subordinate processor.