A disclosed method may include (1) generating a test packet that includes an inner packet encapsulated within an outer packet, (2) adding, to the test packet, an amount of padding data that increases a total size of the test packet to a certain threshold, (3) forwarding, via a transport layer protocol, the test packet along a network path that leads from a source node to a destination node by way of a tunnel, (4) receiving the inner packet from the destination node after the destination node extracts the inner packet from the test packet, and (5) determining, based at least in part on receiving the inner packet from the destination node, that a maximum transmission unit of the network path is greater than or equal to the total size of the test packet as increased by the amount of padding data. Various other apparatuses, systems, and methods are also disclosed.

Disclosed is an electronic device that receives a packet of a content image including a plurality of frames from an external device, transmits a signal indicating whether a packet is received, including a request for a bit rate of an image in a transmitted signal, receives a packet with a changed bit rate of the image based on the request, and displays the image on the display based on the received packet.

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

Systems and techniques are described for a path maximum transmission unit (MTU) discovery method that allows the sender of IP packets to discover the MTU of packets that it is sending over a conduit to a given destination. The MTU is the largest packet that can be sent through the network along a path without requiring fragmentation. The path MTU discovery method actively probes each sending path of each conduit with fragmentation enabled to determine a current MTU and accordingly increase or decrease the conduit MTU. The path MTU discovery process is resilient to errors and supports retransmission if packets are lost in the discovery process. The path MTU discovery process is dynamically adjusted at a periodic rate to adjust to varying network conditions.

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 satellite link based on the one or more data profiles, monitoring reporting times of different data sources of different hubs over time, 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 inserting the allocated preamble codes into packets of each of the data sources.

Methods, apparatuses, and computer readable media for extreme high throughput (EHT) physical layer data rate. An apparatus of an access point (AP) comprising processing circuitry configured to encode an EHT capabilities element, the EHT capabilities element comprising a maximum media access control (MAC) protocol data unit (MPDU) in an aggregated MPDU (A-MPDU) length exponent subfield. The processing circuitry further configured to configure the AP to transmit the EHT capabilities element to a station (STA), and determine a maximum A-MPDU length based on two raised to a power of a constant plus a value of the A-MPDU length exponent subfield. The processing circuitry further configured to encode MPDUs in an A-MPDU, where the A-MPDU is encoded to be less than or equal to the maximum A-MPDU length.

Described embodiments provide systems and methods for adaptive packet size adjustment for UDT or similar protocols, responsive to actual network conditions. Upon detection of a black hole or a size or range of sizes of packets that are repeatedly lost, the system may subdivide packets matching the size or range into smaller subpackets. The receiving device may receive each subpacket and reassemble the original packet, allowing successful communication. Other packets, both smaller and larger than the identified size or range, may be transmitted normally, avoiding drastic reductions to congestion windows or application of other congestion avoidance features, or reducing the MTU value to avoid the black hole range while sacrificing overall useable bandwidth. As a result, the system may more efficiently and reliably communicate large data payloads.

Networking devices, systems, and methods are provided. In one example, a method includes receiving a packet at a networking device; evaluating the packet; based on the evaluation of the packet, truncating the packet from a first size to a second size that is smaller than the first size; and storing the truncated packet in a buffer prior to transmitting the truncated packet with the networking device.

The present invention relates to a method for sending a data packet from a first communication unit of a communication system via a transmission channel that is shared with at least one further communication unit. The method comprises determining a current access priority for the shared transmission channel by the first communication unit, wherein the current access priority is directed towards data currently transmitted over the transmission channel. The data packet is segmented into packet segments, wherein the packet segments have a priority value which corresponds to a priority value of the data packet. The method also comprises sending the packet segments from the first communication unit via the shared transmission channel, wherein the packet segments are sent successively depending on the priority value and the current access priority.

Methods and systems for providing files of variable sizes based on device and/or network conditions are described herein. The system may determine a plurality of bandwidth ranges. The system may also determine a plurality of file classes, and each different file class may be associated with a different bandwidth range. In some scenarios, the system may convert a file into a plurality of modified files. Each modified file may have a different file size and correspond to a different file class. The file and/or modified files may be provided to other devices based on various factors, such as bandwidth, available storage space, and/or display capabilities of user devices.