The present disclosure relates to a method and an apparatus for detecting a maximum transmission unit (MTU) value. The data sender forms a first detection packet according to a first preset rule based on its MTU value. The data sender sends the first detection packet to a data receiver. The data sender receives a second detection packet from the data receiver. The data sender determines an MTU value included in the second detection packet as an MTU value of data transmission between the data sender and the data receiver.

Systems and methods for managing a data packet's maximum transmission unit (MTU) limit in an in-band telemetry (INT) network are disclosed. The methods include a downstream network element receiving a packet with INT instructions and in response to determining that adding its own metadata would exceed the allowed MTU limit at its egress interface, generating and forwarding a telemetry report containing existing and new metadata to the designated collector, and forwarding the received packet without any metadata to the next hop.

The methods forward the telemetry report to the collector when the packet's MTU limit is exceeded and thereby avoids uncontrolled growth of the packet size.

The present disclosure relates to a method and an apparatus for detecting a maximum transmission unit (MTU) value. The data sender forms a first detection packet according to a first preset rule based on its MTU value. The data sender sends the first detection packet to a data receiver. The data sender receives a second detection packet from the data receiver. The data sender determines an MTU value included in the second detection packet as an MTU value of data transmission between the data sender and the data receiver.

The present disclosure provides an electronic apparatus, a central node apparatus and a network side apparatus, a transmission method and a configuration method. The electronic apparatus for user equipment UE side includes: a transmission mode determining device configured for determining, based on service type of uplink transmission data that is to be transmitted to a network side apparatus by the electronic apparatus for UE side, whether to adopt a transmission mode in which the uplink transmission data is transmitted to a central node apparatus such that the uplink transmission data is transmitted to the network side apparatus. The electronic apparatus, the central node apparatus and the network side apparatus, the transmission method and the configuration method according to the present disclosure can implement at least one of saving network resources, reducing signaling overhead, and reducing power loss.

Technologies for dynamically managing a batch size of packets include a network device. The network device is to receive, into a queue, packets from a remote node to be processed by the network device, determine a throughput provided by the network device while the packets are processed, determine whether the determined throughput satisfies a predefined condition, and adjust a batch size of packets in response to a determination that the determined throughput satisfies a predefined condition. The batch size is indicative of a threshold number of queued packets required to be present in the queue before the queued packets in the queue can be processed by the network device.

A device and a method for communicating with a link partner device. The device may include a fragmentation unit configured to fragment a packet into multiple fragments if a size of the packet is greater than a maximum fragment size, a packet control header unit configured to generate a packet control header for a packet or each fragment of the packet, and a transceiver configured to send the packet or the fragments of the packet with the packet control header via a connection between the device and the link partner device. The packet control header may include at least one of a traffic control identifier field for identifying a data stream to which the packet belongs, a priority field for indicating a priority for the packet, or a data flow control field for congestion control between the device and the link partner device.

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.

The described technology is generally directed towards selecting, by user equipment, a selected maximum transmission unit (MTU) packet size for wireless data transfer based on radio signal conditions. In one aspect, reference signal received power (RSRP) and reference signal received quality (RSRQ) are used to select the MTU packet size, e.g., by using RSRP and RSRQ as indices to a lookup table of predetermined MTU packet sizes, such as previously determined by field testing. In general, smaller MTU packet sizes are used with poorer quality radio signal conditions. The selected MTU packet size may be increased or decreased based on actual performance data and/or based on changed radio signal conditions, such as for a subsequent data transfer session. The user equipment may comprise a Cat-M device that transfers data related to Machine-Type Communications (MTC)/Machine to Machine (M2M) communications.

An 802.11-compliant device for high throughput is disclosed. A plurality of TCP packets received in a buffer for transmission are stored. The plurality of TCP packets can be aggregated as A-MSDU sub-frames to form a A-MSDU frame in accordance with an IEEE 802.11 standard. Additionally, a plurality of A-MSDU frames can be aggregated as A-MPDU sub-frames to form a A-MPDU frame. The A-MPDU frame is compliant with a number of allowable sub-frames and a maximum size in accordance with an 802.11 standard. The A-MPDU frame is sent for transmission as an IEEE 802.11 packet.

A method, a device, and a non-transitory storage medium provide a network evaluation service. The service collects live network traffic data for a client device in a network; stores a benchmark pattern model; determines a category of the live network traffic data based on a segment size; detects a first traffic pattern of the live network traffic data based on measured segment parameters for the category; matches the first traffic pattern to a second traffic pattern in the benchmark pattern model to identify a result; compares the live network traffic data with a benchmark application pattern from the benchmark pattern model; and identifies, based on the comparing, a level of degraded performance in the network.