Aspects of the subject disclosure may include, for example, receiving information about a data flow for radio communication between the radio access network and user equipment, classifying the data flow as one of a large data flow and a small data flow, adjusting priority of the data flow by reducing relative priority of the data flow responsive to classifying the data flow as a large data flow, and communicating data including the data flow between the radio access network and the user equipment according to the adjusted priority. Other embodiments are disclosed.

A computing system is configured to execute a computer program on a server and to provide a video stream of the program output to a geographically remote client over a communication network. The computing system is further configured to provide executable content of the computer program to the client over the communication network in parallel with the video stream. When a sufficient amount of the executable content has been provided to the client execution of the computer program is transitioned from the server to the client. The transition optionally includes communicating a state of the computer program from the server to the client. The executable content can be provided to the client in an order that is determined based on the state of the computer program. Those parts of the executable content deemed most likely to be necessary to support game play on the client are given priority.

Provided are systems, methods and computer program code for transmitting vehicle data to remote monitoring systems using a low bandwidth protocol.

A mobile communication system includes a control device and a base station device. Data communication between the control device and the base station device is conducted using a fixed-length data size and a variable-length data size. The control device transmits information indicating whether a data size of the data communication has a fixed length or a variable length. The base station device receives the information from the control device.

Apparatuses, methods, and systems for coordinated access to a wireless link through data profiles are disclosed. One method includes receiving through the wireless link, by each hub associated with a base station, one or more data profiles from a network management element, receiving, by each hub, data from data sources associated with the hub, controlling, by each hub, a timing of communication of the data for each of the data sources from the hub to the base station through the wireless link based on the one or more data profiles, allocating preamble codes to each of the data sources, wherein different preamble codes are allocated to different data sources of different hubs that report within a margin of time of each other, and including the allocated preamble codes with the data of each of the data sources.

Aspects of the subject disclosure may include, for example, receiving information about a data flow for radio communication between the radio access network and user equipment, classifying the data flow as one of a large data flow and a small data flow, adjusting priority of the data flow by reducing relative priority of the data flow responsive to classifying the data flow as a large data flow, and communicating data including the data flow between the radio access network and the user equipment according to the adjusted priority. Other embodiments are disclosed.

The technologies described herein are generally directed to modeling radio wave propagation in a fifth generation (5G) network or other next generation networks. For example, a method described herein can include, for a network application, identifying, by a system comprising a processor, a characteristic value of a performance characteristic associated with an uplink connection enabled via a network of a user equipment to application server equipment hosting the network application. The method can further include, based on the characteristic value and a criterion, selecting, by the system, a first packet size for the uplink connection. The method can further include communicating, by the system, to the user equipment, the first packet size for use with the uplink connection.

Implementations of the present disclosure are directed to systems and methods for reducing the size of packet headers without reducing the range of packet lengths supported. A packet header includes a fixed-width length field. Using a linear encoding, the maximum packet size is a linear function of the fixed-width length field. Thus, to expand the range of sizes available, either the granularity of the field must be decreased (e.g., by changing the measure of the field from flits to double-flits) or the size of the field must be increased (e.g., by changing the size of the field from 4 bits to 5 bits). However, by using a non-linear encoding, the difference between the minimum and maximum size can be increased without decreasing the granularity within a first range of field values and without increasing the size of the length field.

The method of some embodiments controls maximum transmission unit (MTU) size for transmitting data messages of a flow through a gateway of a datacenter. The method, on a host computer operating in the datacenter and executing a source machine for a data message flow, receives an identifier of an MTU size associated with the gateway operating in the datacenter. The method receives, from the source machine, a data message of the flow to be sent through the gateway, where the data message comprises a frame that exceeds the identified MTU size. After determining that the frame includes an indicator specifying that the frame should not be fragmented, the method directs the machine to use smaller size frames in the data messages of the flow. After receiving smaller size frames for the data messages of the flow, the method forwards the data messages to the gateway.

There is provided a technique of time-sensitive transmission of Ethernet traffic in IET-blind network. A source endpoint network node receives expedited and non-expedited Ethernet frames; for each non-expedited Ethernet frame: detects a pre-provisioned designated non-expedited tunnel with a destination endpoint network node corresponding to a destination address specified in the Ethernet frame, segments non-expedited Ethernet frame into a plurality of segments, encapsulates each segment in accordance with the designated non-expedited tunnel; and sends the encapsulated segments to the destination endpoint network node via the designated non-expedited tunnel. When the designated non-expedited tunnel is constituted by a plurality of successive sub-tunnels (e.g. corresponding to a PDU-session of 5G), the technique further comprises initial encapsulating each segment in accordance with a first of successive sub-tunnels and, when swapping to a next sub-tunnel, relaying the encapsulation of each segment according to a network protocol characterizing the next sub-tunnel.